JP2011092132A - Fishline-connecting device, method for connecting fishline, and fishing rig - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fishline-connecting device capable of simply connecting the fishline by one touch; to provide a method for connecting the fishline; and to provide a fishing rig. <P>SOLUTION: The fishline-connecting device 10 connecting a first and a second fishlines 41 and 42 through a connecting device body 20 includes the connecting device body 20 having a first connecting part 22 for connecting the first fishline 41 on one end side, and a second connecting part 24 for connecting the second fishline 42 on the other end side, and a cylindrical member 30 arranged at the periphery of at least one of both the connecting parts 22 and 24. The connecting parts 22 and 24 have tapered shapes. The inner diameter of the cylindrical member 30 is nearly equal to those of the maximum diameter parts of the connecting parts 22 and 24, and the cylindrical member includes a diameter-enlarged part 31 at the end part which is present at the maximum diameter part side. The fishline corresponding to the connecting part is held between at least one of both the connecting parts 22 and 24 and the cylindrical member 30 to connect the connecting part to the fishline, and when the connecting part at which the cylindrical member 30 is not arranged is present, the corresponding fishline is connected to the connecting part at which the cylindrical member is not arranged. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a fishing line coupling tool, a fishing line coupling method, and a fishing device, and more particularly, a fishing line coupling tool, a fishing line coupling method, and a fishing line that can easily couple a trunk line and Harris and that can easily adjust the direction of the tip of a fishing hook. Regarding the device.

  The fishing tackle shown in FIG. 13 is widely used. In this fishing tackle, a device is attached to a fishing rod 8, and this device connects a main thread 2 to a tip of a road thread 1 via a salcan 6 and ties Harris 3 to branch to the main thread 2. The fishing hook 5 is connected to the tip of Harris 3. In such a mechanism, since it takes time to tie the trunk yarn 2 and Harris 3, a connecting tool that can easily connect the trunk yarn 2 and Harris 3 is known (for example, see Patent Document 1). ).

Patent Document 1 discloses a connector shown in FIG. In this connector, the metal wire 101 is folded in two, and the pinching portion 105 of the Harris 104 is bent at the base end portions of both sides 102 and 103, and the intermediate portion between both sides 102 and 103 is bent into a semicircular shape. Then, an automatic Harris stop member 109 is formed by bending the introduction port 106 of the Harris 104 into a semicircular shape at the tip portion and providing an annular attachment portion 108 to the trunk yarn 107, and separately from this, a transparent hard The bead 110 is molded with a synthetic resin material in a state where the annular mounting portion 108 of the automatic Harris stop member 109 is inserted and the other is exposed to the outside. An orientation hole 111 is provided therethrough.
The knots 113 and 114 are formed above and below the trunk thread 107 through the trunk threading vertical hole 111 to prevent the beads 110 from moving up and down, and the Harris 104 having the knot 112 formed on the end side in advance is introduced into the inlet port. After passing through 106, pulling toward the pinching stop portion 105 and shifting it to the pinching state, the Harris 104 is attached to the trunk thread 107. When the Harris 104 is pulled toward the fishhook 115, the Harris 104 slides in the direction of the fishhook 115, and the knot 112 is configured to be locked at both sides 102 and 103.
According to the invention described in Patent Document 1, there is an effect that the Harris 104 can be connected and exchanged with the trunk thread 107 to which the connecting tool is attached by one touch.

Japanese Unexamined Patent Publication No. 2001-197854 (paragraph 0005, FIG. 1)

However, according to the connector according to Patent Document 1, the thickness of the usable Harris 104 is limited to the interval between the both sides 102 and 103, and the range of the usable thickness of the Harris 104 is very narrow. there were. Furthermore, since the Harris 104 slides while being sandwiched between the sides 102 and 103, the Harris 104 is squeezed by the sides 102 and 103 when it is slid, and the strength of the Harris 104 is weakened. . Furthermore, even if the tip of the fishhook 115 is directed directly upward as shown in FIG. 14, the tip of the fishhook 115 changes due to the Harris 104 being squeezed and contracted, so that the tip of the fishhook 115 is moved to a desired direction. There was also a problem that it was difficult to turn.
In the first place, there is no known connection tool that can connect a fishing line represented by Patent Document 1 that can connect a fishing line with one touch.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a fishing line connector, a fishing line connection method, and a fishing device capable of easily connecting a plurality of fishing lines with one touch. .
Another object of the present invention is to provide a fishing line coupling tool, a fishing line coupling method, and a fishing device capable of easily coupling a metal wire Harris to a trunk thread with one touch.
Still another object of the present invention is to provide a fishing line coupling device and a fishing line coupling method that can connect Harris to a trunk thread with a simple one touch, and can easily exchange Harris, and can fix the direction of a fishhook at the tip of Harris in a predetermined direction. And providing a fishing device.

  According to the fishing line connector according to claim 1, the subject is a fishing line connector that connects a plurality of fishing lines to each other, and has a first connecting part that connects the first fishing line to one end side. A connector main body having a second connecting portion for connecting the second fishing line to the end side, and a cylindrical member disposed around at least one of the first and second connecting portions, The connecting portion is a portion from the thickest maximum diameter portion provided at a predetermined position on the end side of the connector main body to the thinnest minimum diameter portion located on the opposite side of the end portion from the maximum diameter portion. However, the cylindrical member has a tapered shape in which the diameter gradually decreases from the maximum diameter portion to the minimum diameter portion, and the cylindrical member has an inner diameter that is substantially the same as the maximum diameter portion. When the cylinder is arranged around the connecting portion, the outermost The end portion located on the diameter portion side includes an enlarged diameter portion that increases the inner diameter, and at least one of the first and second connection portions and the at least one connection portion between the cylindrical member. The fishing line corresponding to is sandwiched to connect the at least one connecting part and the corresponding fishing line, and when there is the connecting part where the cylindrical member is not arranged, the cylindrical member is not arranged. Connecting the first fishing line and the second fishing line to each other via the connector body by connecting the fishing line corresponding to the connecting part where the cylindrical member is not disposed to the connecting part; It is solved by.

Since it comprises in this way, a 1st fishing line and a 2nd fishing line can be easily connected by one touch.
Further, the fishing line corresponding to the at least one connecting portion is sandwiched between at least one of the first and second connecting portions and the cylindrical member, and the at least one connecting portion and the corresponding Since the fishing line to be connected can be connected, the connection state between the connecting portion and the fishing line can be easily released, and the fishing line can be replaced quickly and easily. Therefore, the fishing line can be easily exchanged at the fishing spot.

  In addition, since the cylindrical member has an enlarged diameter portion that increases the inner diameter at the end located on the maximum diameter portion side when arranged around the connecting portion, the cylindrical member is connected to the cylindrical member. Workability at the time of inserting a fishing line between parts is improved. In addition, when the cylindrical member is disposed around the connecting portion, the enlarged diameter portion of the cylindrical member spreads in the same direction as the tapered shape of the connecting portion of the connector main body, and therefore between the enlarged diameter portion and the connecting portion. The fishing line can be sandwiched, and the contact surface between the fishing line and the connecting portion and the inner wall of the cylindrical member increases, so that the fishing line can be more firmly fixed to the connector main body.

Further, the first fishing line is a trunk thread, the second fishing line is Harris made of a metal wire, and at least one of the first and second connection parts is the second connection part. The connecting portion where the cylindrical member is not arranged may be the first connecting portion, and the cylindrical member may be made of metal.
With such a configuration, it is possible to quickly and easily connect the metal wire Harris, which has been impossible in the past, and to connect the metal wire Harris at the fishing spot quickly and easily with one touch.
Because the metal wire Harris is sandwiched between the taper-shaped connecting portion and the cylindrical member, the metal wire Harris does not rotate around the axis, so that the fishhook does not swing around the metal wire Harris tip. Is fixed, the direction of the tip of the fishhook at the tip of the metal wire Harris can be easily fixed.
Further, according to the present invention, the direction of the tip of the fishhook at the tip of the metal wire Harris can be easily fixed, and the metal wire Harris can be replaced with one touch at the fishing spot. It is said that metal wire Harris will be used for fishfish fishing, etc., which is very strong and requires frequent change of fishing hooks, and fish that needs to use hard and strong fishing line due to small reaction when fish enters the mouth. New fishing methods are possible.

Further, the first fishing line is a trunk thread, and the second fishing line is a non-metallic Harris or metal whose main component is at least one material of a group including synthetic resin, natural fiber, and synthetic fiber. Harris consisting of a line, wherein at least one of the first and second connecting portions is the second connecting portion, and the connecting portion where the cylindrical member is not disposed is the first connecting portion. The cylindrical member is made of a synthetic resin, and has a groove portion extending in the axial direction of the cylindrical member on the outer surface, the groove portion of the Harris coil wound around the wall of the cylindrical member. Of these, a portion arranged outside the cylindrical member may be configured to be housed.
When a cylindrical member made of a hard material such as metal is used, when a strong force is applied, non-metallic Harris slips through between the cylindrical member and the connector main body to obtain a strong connecting force. However, in the present invention, since the cylindrical member is made of a synthetic resin, it is possible to connect the non-metallic Harris with the fishing line connector of the present invention. Further, the cylindrical member includes a groove portion extending in an axial direction of the cylindrical member on an outer surface, and the groove portion is outside the cylindrical member of the Harris wound around the wall of the cylindrical member. The non-metallic Harris is wound around the wall of the cylindrical member, and the portion arranged outside the cylindrical member is stored in the groove portion. It becomes possible to firmly fix the metallic Harris to the second connecting portion.
In addition, since the cylindrical member has the groove on the outer surface, it is possible to prevent the finger from slipping on the outer surface of the cylindrical member when the cylindrical member is disposed around the connecting portion. Further, the groove serves as a mark for confirming the movement angle of Harris and the cylindrical member when correcting the direction of the tip of the fishing hook at the tip of Harris.

You may comprise the said connector main body so that it may consist of the linear rod-shaped body which is not bent, or the rod-shaped body bent between the said 1st connection part and the said 2nd connection part.
For example, when the first fishing line is a trunk thread and the second fishing line is Harris, if the Harris is short, the hook is moved away from the trunk thread as a folded rod-shaped body. If the length is long, it is possible to make a device that is easy to use according to the length of Harris, such as preventing the yarn from becoming tangled as a linear rod-shaped body.

  According to the fishing line connecting method according to claim 5, the subject has a first connecting part for connecting the trunk thread on one end side and a second connecting part for connecting the metal wire Harris on the other end side. A fishing line connecting method for connecting the trunk thread and the metal wire Harris via a fishing line connecting tool provided with a tool main body, wherein the connecting portion is provided at a predetermined position on the end side of the connecting tool main body. A portion from the thickest maximum diameter portion to the thinnest minimum diameter portion located on the opposite side of the end portion from the maximum diameter portion is formed in a substantially circular cross section, and the maximum diameter portion to the minimum diameter It has a taper shape with a gradually decreasing diameter over the portion, and a trunk yarn connecting step of connecting the stem yarn to the first connecting portion, and having the same diameter as the maximum diameter portion of the second connecting portion. The connector main body is inserted into a cylindrical member having an inner diameter, and the connector main body The cylindrical member insertion step of arranging the cylindrical member around the position having a diameter smaller than the inner diameter of the cylindrical member, and the metal wire Harris is inserted from the end on the second connecting portion side And a Harris insertion step that is arranged in a gap between the connector body and the cylindrical member, and the cylindrical member is held while the metal wire Harris is held between the cylindrical member and the connector body. A metal wire Harris connected to the connector main body by moving the metal wire Harris between the cylindrical member and the second connecting portion by moving the second connecting portion to the maximum diameter portion side. And a coupling step.

With this configuration, it is possible to quickly and easily connect the metal wire Harris, which has been impossible in the past, and to connect the metal wire Harris at the fishing spot quickly and easily with one touch.
Further, while holding the metal wire Harris between the cylindrical member and the connector main body, the cylindrical member is moved to the maximum diameter portion side of the second connecting portion, and the metal wire is moved. Since the metal wire Harris connecting step of connecting Harris to the connector main body by sandwiching Harris between the cylindrical member and the second connecting portion is provided, the second connecting portion and the metal wire Harris The connection state between them can be easily released, and the metal wire Harris can be exchanged quickly and easily. Therefore, the metal wire Harris can be easily exchanged at the fishing spot.
Because the metal wire Harris is sandwiched between the taper-shaped connecting portion and the cylindrical member, the metal wire Harris does not rotate around the axis, so that the fishhook does not swing around the metal wire Harris tip. Is fixed, the direction of the tip of the fishhook at the tip of the metal wire Harris can be easily fixed.
Moreover, since the connection state between the second connecting portion and the metal wire Harris can be easily released, the direction of the tip of the fishhook connected to the tip of the metal wire Harris can be easily corrected.
Further, according to the present invention, the direction of the tip of the fishhook at the tip of the metal wire Harris can be easily fixed, and the metal wire Harris can be replaced with one touch at the fishing spot. It is said that metal wire Harris will be used for fishfish fishing, etc., which is very strong and requires frequent change of fishing hooks, and fish that needs to use hard and strong fishing line due to small reaction when fish enters the mouth. New fishing methods are possible.

Further, prior to the cylindrical member insertion step, a tip end side needle tip portion, a rear end side needle barrel portion provided continuously and integrally with the needle tip portion, and the needle barrel portion, A portion from the thickest maximum diameter portion provided at a predetermined position on the rear end side to the thinnest minimum diameter portion positioned on the needle tip side from the maximum diameter portion is formed in a substantially circular cross section. A taper portion having a tapered shape with a gradually decreasing diameter from the maximum diameter portion to the minimum diameter portion, and inserting the needle barrel portion of the fishing hook into the cylindrical member, and the needle barrel portion A step of arranging the cylindrical member around a position having a diameter smaller than the inner diameter of the cylindrical member, and inserting the metal wire Harris from the rear end, and the cylindrical member and the needle cylinder A step of disposing the metal wire Harris between the cylindrical member and the front The cylindrical member is moved to the maximum diameter portion side of the tapered portion while being held between the needle barrel portion and the metal wire Harris is sandwiched between the tapered portion and the cylindrical member. The fishhook connecting step of connecting the metal wire Harris to the fishhook by, after the metal wire Harris connecting step, while holding the metal wire Harris between the cylindrical member and the connector body, By moving the cylindrical member to the minimum diameter portion side to loosen the connection state between the metal wire Harris and the second connecting portion, and moving the metal wire Harris in the circumferential direction of the connector main body. After adjusting the needle tip portion to face upward of the fishing device, the cylindrical member is moved again to the maximum diameter portion side of the second connecting portion, and fixed. Correct the direction of the tip of the fishhook. It may be configured to perform the steps of.
Since it comprises in this way, a metal wire Harris can be connected to a fishing hook quickly and easily by one touch. Further, it is possible to connect the fishhook and the metal wire Harris in advance, and connect the metal wire Harris with the fishhook to the trunk thread using the connector main body after moving to the fishing ground. As a result, the metal wire Harris device that is difficult to carry in the completed device state can be completed only by connecting the fishhook and metal wire Harris, and the device can be completed at the fishing spot. spread.
In addition, since the step of correcting the direction of the tip of the fishhook is performed after the metal wire Harris connecting step, unlike the case of connecting the fishhook to Harris while determining the direction of the tip of the fishhook, the hook of the fishhook is surely It is possible to point the tip in a desired direction. The direction of the tip of the fishhook is a critical factor that affects the fishing results, and as a result, it is possible to improve the fishing results.

  According to the fishing line connecting method according to claim 7, the subject has a first connecting part for connecting a trunk thread on one end side, and a group including a synthetic resin, a natural fiber, and a synthetic fiber on the other end side. The trunk thread and the non-thread are connected via a fishing line connector having a connector main body having a second connecting part for connecting a non-metallic Harris having at least one material as a main component and having elasticity in a radial direction. A fishing line coupling method for coupling metal-based Harris, wherein the coupling portion is formed from a thickest maximum diameter portion provided at a predetermined position on an end side of the connector main body, from the maximum diameter portion to the end portion. The portion up to the thinnest minimum diameter portion located on the opposite side is formed in a substantially circular cross section, and has a tapered shape in which the diameter gradually decreases from the maximum diameter portion to the minimum diameter portion. A main thread connecting step of connecting the main thread to the connecting portion of The connector main body is inserted into a cylindrical member having an inner diameter substantially the same as the maximum diameter portion of the second connecting portion, and the connecting member main body has a diameter smaller than the inner diameter of the cylindrical member. A cylindrical member insertion step of arranging the cylindrical member around the position, and the non-metallic Harris is inserted from an end on the second connecting portion side, and the connector main body and the cylindrical member A Harris insertion step to be disposed in the gap, and the non-metallic Harris that has passed through the gap between the connector body and the cylindrical member is inserted at least once more from the end on the second connection portion side, The periphery of the wall of the cylindrical member is wound in the axial direction of the cylindrical member, and a portion of the non-metallic Harris that is disposed outside the wall of the cylindrical member is disposed on the outer surface of the cylindrical member. In the groove portion that is carved to extend in the axial direction of the cylindrical member. And the non-metallic Harris is held between the cylindrical member and the connector main body and in the groove portion, while the cylindrical member is held in the maximum diameter portion of the second connecting portion. A non-metallic Harris connecting step of connecting to the connector main body by moving the non-metallic Harris between the cylindrical member and the second connecting portion. It is solved by.

With this configuration, non-metallic Harris can be quickly and easily connected with one touch, and non-metallic Harris can be quickly and easily replaced with one touch at a fishing spot.
Further, the cylindrical member is moved to the maximum diameter portion side of the second connecting portion while holding the non-metallic Harris between the cylindrical member and the connector main body and in the groove portion. Since the non-metallic Harris connecting step of connecting the non-metallic Harris to the connector main body by sandwiching the non-metallic Harris between the cylindrical member and the second connecting portion, The connection state between the connecting portion and the non-metallic Harris can be easily released, and the non-metallic Harris can be replaced quickly and easily. Therefore, non-metallic Harris can be easily exchanged at the fishing spot.
The non-metallic Harris is sandwiched between the tapered connecting part and the cylindrical member, so the non-metallic Harris does not rotate around the axis and does not swing to the tip of the non-metallic Harris. If the fishhook is fixed in this manner, the direction of the tip of the fishhook at the tip of the non-metallic Harris can be easily fixed.
Moreover, since the connection state between the second connecting portion and the nonmetallic Harris can be easily released, the direction of the tip of the fishing hook connected to the tip of the nonmetallic Harris can be easily corrected.

In addition, a step of connecting the non-metallic Harris to a fishing hook is performed before the cylindrical member inserting step, and the non-metallic Harris is connected to the cylindrical member after the non-metallic Harris connecting step. The cylindrical member is moved to the minimum diameter portion side while being held between the tool body and in the groove portion to loosen the connection state between the non-metallic Harris and the second connection portion, and The metal-based Harris is moved in the circumferential direction of the connector main body so that the tip of the fishhook is adjusted so as to face upward of the fishing device. You may comprise so that the process of correcting the direction of the said needle-tip part may be performed by moving to the said largest diameter part side of the connection part, and fixing.
Since it comprises in this way, non-metallic Harris can be connected to a fishing hook quickly and easily with one touch. Moreover, after connecting to a fishing hook and a nonmetallic Harris beforehand, after moving to a fishing ground, it becomes possible to connect a nonmetallic Harris with a fishing hook to a trunk thread using a connector main part.
Also, since the step of correcting the direction of the tip of the fishhook is performed after the non-metallic Harris connecting step, unlike the case of connecting the fishhook to Harris while determining the direction of the tip of the fishhook, The needle tip can be directed in a desired direction. The direction of the tip of the fishhook is a critical factor that affects the fishing results, and as a result, it is possible to improve the fishing results.

  According to the fishing device according to claim 9, the subject is a fishing device comprising a trunk thread and Harris having an end connected to the trunk thread via a fishing line connector, The fishing line coupler has a first coupling part for coupling the trunk thread on one end side and a second coupling part for coupling the Harris on the other end side, the first and the second A cylindrical member disposed around at least one of the connecting parts, and the connecting part from the thickest maximum diameter part provided at a predetermined position on the end side of the connector main body, A portion from the largest diameter portion to the thinnest smallest diameter portion located on the opposite side of the end portion is formed in a substantially circular cross section, and the diameter gradually decreases from the largest diameter portion to the smallest diameter portion. The cylindrical member has a shape, and an inner diameter of the cylindrical member is substantially the same as the largest diameter portion. An end portion located on the maximum diameter portion side when arranged around the connecting portion, and having an enlarged diameter portion that increases the inner diameter, and at least one of the first and second connecting portions. The trunk yarn or Harris corresponding to the at least one connecting portion is sandwiched between the cylindrical member and the cylindrical member, so that the at least one connecting portion and the corresponding stem yarn or Harris are When there is the connecting portion that is connected and the cylindrical member is not disposed, the trunk thread corresponding to the connecting portion where the cylindrical member is not disposed or the connecting portion where the cylindrical member is not disposed By connecting Harris, the problem is solved by connecting the trunk yarn and Harris through the connector body.

  Further, it further comprises a fishhook connected to the Harris, the Harris is made of a metal wire, and the fishhook is provided at the tip end side and the rear end side provided integrally with the tip end portion. Of the needle body, and the thinnest minimum diameter portion located on the needle tip side of the maximum diameter portion from the thickest maximum diameter portion provided at a predetermined position on the rear end side of the needle body portion And a tapered portion having a tapered shape with a gradually decreasing diameter from the maximum diameter portion to the minimum diameter portion, and the fishing hook includes the taper portion and The metal wire is sandwiched between the cylindrical member made of a substantially cylindrical body having an inner diameter that is substantially the same as the maximum diameter portion, so that the metal wire is connected to the cylindrical member. Good.

According to the present invention, the first fishing line and the second fishing line can be easily connected with one touch.
Further, the fishing line corresponding to the at least one connecting portion is sandwiched between at least one of the first and second connecting portions and the cylindrical member, and the at least one connecting portion and the corresponding Since the fishing line to be connected can be connected, the connection state between the connecting portion and the fishing line can be easily released, and the fishing line can be replaced quickly and easily. Therefore, the fishing line can be easily exchanged at the fishing spot. In addition, since the connection state between the connecting portion and the fishing line can be easily released, for example, when the fishing line connector of the present invention is used for the trunk thread and Harris, the tip of the fishing hook connected to the tip of Harris The orientation can be easily corrected.

It is explanatory drawing which shows the fishing gear using the fishing device of one Embodiment of this invention. It is explanatory drawing of the device for fishing of one Embodiment of this invention. It is explanatory drawing which shows the coupling tool main body and sleeve of one Embodiment of this invention. It is explanatory drawing which shows the procedure which connects metal wire Harris to the fishing hook of one Embodiment of this invention. It is explanatory drawing which shows the procedure which connects a metal wire trunk thread and metal wire Harris by the connector main body of one Embodiment of this invention. It is explanatory drawing which shows the connector main body of other embodiment of this invention. (A) is a side view of a bead of still another embodiment of the present invention, and (B) is a cross-sectional view taken along line AA in (A). It is explanatory drawing which shows the connection of the nonmetallic trunk yarn and metal wire Harris by a bead and a connector main body. It is explanatory drawing which shows the connection of the nonmetallic trunk thread and nonmetallic Harris by a bead and a connector main body. It is explanatory drawing which shows the connection of the trunk thread and nonmetallic Harris by other embodiment of this invention. It is explanatory drawing which shows the squid angle in which the bead was embed | buried. It is explanatory drawing which shows the example which used the connector main body as a balance. It is explanatory drawing which shows the device for general fishing. It is explanatory drawing which shows the coupling tool of the conventional fishing line.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that members, arrangements, and the like described below do not limit the present invention, and it goes without saying that various modifications can be made in accordance with the spirit of the present invention.
In the present specification, the term “tapered” means that the specific portion of the shaft body is thinner at the other end than at the one end. The shaft body formed in this “tapered shape” only needs to have a smaller thickness on the other end side than the thickness on one end side of the specific portion, and the cross section is a circle, an ellipse, a rectangle, other polygons, etc. It may be any shape. For example, when the cross section is rectangular, the width on the upper and lower sides may be constant, and the width on the left and right sides may be configured to be larger on the other end side than on one end side. Both of the widths may be configured such that the other end side is larger than the one end side. Further, the width on the upper and lower sides is configured so that the other end side is larger than the one end side, and the width on the left and right sides is formed so that the other end side is smaller than the one end side. It may be formed so that the other end side is smaller than the one end side as a whole.
In addition, in the present specification, the “non-metallic fishing line” refers to a synthetic resin fishing line including a nylon line, a fluorocarbon line, a PE line, a fluoro nylon line, a polyester line, a natural or synthetic fiber fishing line, etc. It does not mean that it does not contain any metal at all, it means synthetic resin fishing line, synthetic resin having elasticity specific to natural or synthetic fiber fishing line, natural fiber, fishing line in general with synthetic fiber as a main component, Metals may be included for property improvement or the like.

The fishing device S of the present embodiment is used in the fishing gear shown in FIG. 1, and as shown in FIG. 2, as shown in FIG. 2, a metal line main thread 41 and one or a plurality of fishing lines connected to the metal line main thread 41. A connector 10 (hereinafter referred to as a connector 10), a metal wire Harris 42 connected to the metal wire trunk thread 41 via each connector 10, and a fishing hook 50 connected to the tip of each metal wire Harris 42; Is composed of.
The metal wire main yarn 41 and the metal wire Harris 42 are a main yarn and Harris made of a metal wire. “Metal wire” means metal teg for fishing, metal wire such as piano wire, tungsten wire, wire, superelastic wire represented by Ni-Ti, or metal stranded wire, these metal wire or metal stranded wire. Including wire with metal coating or resin coating.

The connector 10 is used to connect the metal wire trunk thread 41 and the metal wire Harris 42, and includes the connector main body 20 shown in FIG. 2 or 3 and a pair of sleeves 30 as cylindrical members.
The connector main body 20 is made of a spring material such as a piano wire, a spring stainless steel wire, a phosphor bronze wire, aluminum, etc., and is a substantially cylindrical rod-like body made of metal having a certain degree of elasticity. When manufacturing a fishing device S for small fish such as crucibles that use floating, it is preferable that the connector main body 20 is made of aluminum.
As shown in FIGS. 2 and 3, the connector main body 20 has a shape in which the cross section is a circle and the center in the axial direction is narrowed, and a small diameter portion 21 having a small diameter is formed in the center in the axial direction. The first taper portion 22 as the first connecting portion for connecting the metal line trunk yarn 41 as the first fishing line to the axial one end 23 side, and the second fishing line to the axial other end 25 side. A second taper portion 24 is provided as a second connecting portion for connecting a certain metal wire Harris 42.

  The first taper portion 22 is a region to which the metal wire trunk thread 41 is connected, and is between the thinnest minimum diameter portion 22a on the narrow diameter portion 21 side and the thickest maximum diameter portion 22b on the one end 23 side. This is a region, and a hypotenuse whose diameter increases with a constant gradient from the smallest diameter portion 22a to the largest diameter portion 22b is formed in a linear taper. The first taper portion 22 may be a convex or concave curve whose slope is expressed by a quadratic equation or the like instead of a constant gradient.

The gradient of the first tapered portion 22 is an important factor that determines the strength of the connection between the metal wire trunk thread 41 and the connector main body 20 by the connector 10 of the present embodiment, and the diameter and the minimum diameter of the maximum diameter portion 22b. The difference from the diameter of the portion 22a is 1.2 times or more and less than 2.0 times the diameter of the metal wire main thread 41.
When the difference is smaller than 1.2 times the diameter of the metal wire main thread 41, it is difficult to insert the metal wire main thread 41 between the minimum diameter portion 22a or the small diameter portion 21 and the sleeve 30, and workability is deteriorated. . Further, when the difference is 2.0 times or more the diameter of the metal wire main yarn 41, loosening occurs between the metal wire main yarn 41, the sleeve 30, and the tapered portion 22, and sufficient connection strength cannot be obtained. .

Although the thickness of the metal wire trunk thread 41 is various, the diameter of the metal wire trunk thread 41 here refers to the diameter of the metal wire trunk thread 41 used for connection with the connector main body 20. Since the size of the connector main body 20 and the thickness of the metal wire main thread 41 are selected according to the fish to be fished, the thickness of the metal wire main thread 41 used for the predetermined connector main body 20 is It will be decided to some extent.
Specifically, it is common to use a metal wire main thread 41 of about 0.2 mm to 0.4 mm.

In the present embodiment, the maximum diameter portion 22b is a predetermined distance from the one end 23 of the connector main body 20, for example, a position on the inner side of about 1 to 2 mm, and a predetermined number of metal wire main threads 41 from the minimum diameter portion 22a, for example, The position of the metal wire trunk yarn 41 on the one end 23 side is about 10-18.
Since the maximum diameter portion 22b is positioned at a predetermined distance from the one end 23 of the connector body 20, the diameter of the maximum diameter portion 22b is larger than the one end 23, and the end portion 23 is rounded without a corner from the maximum diameter portion 22b. It can be made into a shape, and the metal wire trunk thread 41 can be prevented from rubbing and being cut by the one end 23.

  Thus, the difference between the diameter of the maximum diameter portion 22b and the diameter of the minimum diameter portion 22a of the taper portion 22 is 1.2 times or more and less than 2.0 times the diameter of the metal wire main thread 41, and The maximum diameter portion 22b is located at a position corresponding to a predetermined number of metal wire trunk yarns 41 from the minimum diameter portion 22a, for example, about 10 to 18 metal wire trunk yarns 41, and the taper portion 22 is maximum from the minimum diameter portion 22a. Since the diameter gradually increases from the diameter portion 22b, it can be stably locked in the sleeve 30 having the same inner diameter over the entire length of the main body portion 32.

As shown in FIG. 3, the sleeve 30 is made of a substantially cylindrical body made of metal such as copper, aluminum (dyed aluminum), brass, nickel, iron, and the like, and has a diameter-expanded portion 31 formed at one end in the axial direction. A body portion 32 other than the diameter portion 31 is provided. For example, it is possible to use a general-purpose copper wire Harris binding sleeve that is generally traded as a fishing tool and having the enlarged diameter portion 31 formed by expanding one end thereof. The thickness of the sleeve 30 and the composition of the metal forming the sleeve 30 are configured such that the fish is deformed by the force applied to the fish hook.
Except when applied to special large fish, the wall thickness of the sleeve 30 is set to about 0.3 to 0.4 mm, and the length of the sleeve 30 is set to about 3 to 6 mm, preferably about 3 mm. When the length of the sleeve 30 is longer than 6 mm, the overall size of the connector 10 increases. Further, when the length of the sleeve 30 is shorter than 3 mm, the holding force of the metal wire trunk thread 41 is weakened, and the sleeve 30 may be deformed or torn.

The enlarged diameter portion 31 is provided at an end portion disposed on the one end 23 side when the sleeve 30 is attached to the first tapered portion 22 of the connector main body 20, and the inner diameter of the sleeve 30 expands toward the end portion. The part that is. Since one end of the sleeve 30, that is, the end portion disposed on the one end 23 side when the sleeve 30 is attached to the first taper portion 22, is provided with the enlarged diameter portion 31, the metal wire in FIG. The trunk thread 41 can be easily inserted into the gap between the sleeve 30 and the connector main body 20. The enlarged diameter portion 31 is provided only at one end of the sleeve 30 because the enlarged diameter portion is provided at the end portion disposed on the narrow diameter portion 21 side when the sleeve 30 is attached to the tapered portion 22 of the connector main body 20. When provided, the gap between the enlarged diameter portion and the taper portion 22 is widened, and the force for sandwiching the metal wire trunk yarn 41 is weakened. As a whole, the sleeve 30 and the first taper portion 22 are connected to the metal wire trunk. This is because the force for holding the thread 41 is weakened. Note that the end portion of the sleeve 30 opposite to the enlarged diameter portion 31 is not flat but is rounded. Since it is configured in this way, workability when inserting the metal wire trunk thread 41 into the gap between the end portion of the sleeve 30 opposite to the enlarged diameter portion 31 and the connector main body 20 is improved.
The diameter-expanded portion 31 has a conical shape obtained by scraping the tip of a metal cylinder (not shown) that is thicker than the sleeve 30, and the sleeve 30 is placed on the same so as to be coaxial. It is formed by hitting with a hammer.

The inner diameter of the main body portion 32 of the sleeve 30 is substantially the same as the maximum diameter portion 22 b of the connector main body 20 to be used, and the maximum diameter portion 22 b of the connector main body 20 is in contact with the inner wall of the main body portion 32. It is thick enough to pass through the entire length. However, when a thick metal wire of 0.9 mm or more is used as the metal wire main thread 41, the inner diameter of the main body portion 32 is larger than the diameter of the maximum diameter portion 22b, and the diameter of the maximum diameter portion 22b and the metal wire main yarn. It is comprised so that it may become smaller than the sum which added the diameter of 40.
Specifically, the inner diameter of the main body 32 is set to about 0.6 to 1.4 mm in accordance with the size and type of fish, the conditions of the fishing ground, and the like.

The second taper portion 24 is a region where the metal wire Harris 42 is connected, and is between the thinnest minimum diameter portion 24a on the narrow diameter portion 21 side and the thickest maximum diameter portion 24b on the other end 25 side. This is a region, and a hypotenuse whose diameter increases with a constant gradient from the minimum diameter portion 24a to the maximum diameter portion 24b is formed in a linear taper.
The second taper portion 24 is formed so as to be symmetric with the first taper portion 22 on the other end 25 side which is the opposite end portion of the first taper portion via the small diameter portion 21. Yes. The configuration of the sleeve 30 used to connect the second taper portion 24 and the metal wire Harris 42 to the second taper portion 24 is the same as that of the first taper portion 22 and the sleeve 30 used in the first taper portion 22. Since it is the same as that of a structure, description is abbreviate | omitted.

  The connector main body 20 of the present embodiment may be used in a straight line as shown in FIG. 3, or may be used by being bent at the small diameter portion 21 as shown in FIGS. . When used in a straight line, the metal wire Harris 42 is not easily entangled with the metal wire trunk thread 41 and is suitable for a device using the long metal wire Harris 42. On the other hand, when bent at the small diameter portion 21, the position of the fishing hook connected to the tip of the metal wire Harris 42 is far from the metal wire trunk 41, which is suitable for the device using the short metal wire Harris 42.

As shown in FIG. 2, the fishing hook 50 includes a tip end 51 a for attaching fishing bait, a bend 51 b, and a needle trunk 52 on the rear end 54 side.
The needle body portion 52 has a substantially circular cross section, and includes a tapered portion 53 at a position close to the rear end 54. The taper portion 53 is a region between the thinnest minimum diameter portion 53a on the bent 51b side and the thickest maximum diameter portion 53b on the rear end 54 side, and is constant from the minimum diameter portion 53a toward the maximum diameter portion 53b. The hypotenuse whose diameter increases with the gradient is formed in a linear taper. Since the structure of the taper part 53 is the same as that of the taper part 22 of the connector main body 20, description is abbreviate | omitted.

A procedure for manufacturing the fishing device S of the present embodiment will be described with reference to FIGS.
First, a fishhook connecting step for connecting the fishhook 50 to the metal wire Harris 42 is performed.
In this step, as shown in FIG. 4A, the fishing hook 50 is inserted into the sleeve 30 from the rear end 54 side. At this time, the fishing hook 50 is inserted while the maximum diameter portion 53 b is in contact with the inner wall of the sleeve 30 main body portion 32. The sleeve 30 is arranged at a position closer to the bend 51b than the minimum diameter portion 53a or the minimum diameter portion 53a. At this time, a gap into which the metal wire Harris 42 can be inserted is formed between the inner wall of the sleeve 30 and the shaft of the fishing hook 50.
Next, as shown in FIG. 4B, the metal wire Harris 42 is inserted from the tip 42 a side into the gap between the inner wall of the sleeve 30 and the shaft of the fishing hook 50, and the tip 42 a of the metal wire Harris 42 is bent more than the sleeve 30. It is located on the 51b side. At this time, as shown in FIG. 4B, the metal wire Harris 42 is disposed on the needle tip portion 51 a side around the needle barrel portion 52 and extends parallel to the axis of the needle barrel portion 52. That is, the metal wire Harris 40 is arranged in a direction around the needle body portion 52 so that the fishing hook 50 bends from the bend 51b toward the needle tip portion 51a. Thereafter, the sleeve 30 is moved toward the rear end 54 of the fishing hook 50 with a strong force with a strong force. Thereby, the metal wire Harris 42 is fixed to the needle tip portion 51a side around the needle barrel portion 52, and swinging is prevented.
Further, since the metal wire Harris 40 is disposed on the side of the needle tip portion 51a around the needle body portion 52, if the metal wire Harris 40 is connected to the trunk thread so as not to rotate, the needle tip portion 51a of the fishing hook 50 is set. It can be fixed upward.

After that, if the tip 42a side of the metal wire Harris 42 seems to protrude from the sleeve 30 for a long time, the metal wire Harris 42 is cut out, and the state shown in FIG. This completes the fishhook connecting step.
Since the metal wire Harris 42 and the fishhook 50 are connected to each other and have a substantially straight line shape without branching, the metal wire Harris 42 and the fishing hook 50 are easily housed. Therefore, it is preferable that the fishing hook connecting process is performed before moving to the fishing ground, the necessary number of metal wire Harris 42 and the fishing hook 50 are manufactured in advance, brought into the fishing ground, and the subsequent processes are performed at the fishing ground. is there.

Next, a trunk yarn coupling step for coupling the metal wire trunk yarn 41 to the coupler main body 20 is performed. In the procedure of FIG. 5, the case where the connector main body 20 is bent will be described. However, even when a linear object as shown in FIG.
In this step, first, the connector main body 20 is inserted into the sleeve 30 from the one end 23 or the other end 25 so that the diameter-expanded portion 31 of the sleeve 30 is on the one end 23 side of the connector main body 20. At this time, the connector main body 20 is inserted while the maximum diameter portion 22 b or the maximum diameter portion 24 b is in contact with the inner wall of the main body portion 32 of the sleeve 30. Thereafter, the sleeve 30 is disposed around the minimum diameter portions 22 a and 24 a or the small diameter portion 21. At this time, a gap is formed between the inner wall of the sleeve 30 and the shaft of the connector main body 20 so that the metal wire trunk thread 41 can be inserted.
Next, as shown in FIG. 5 (A), the metal wire trunk is inserted into the gap between the inner wall of the sleeve 30 and the shaft of the connector main body 20 from one end 23 side of the connector main body 20, that is, from the enlarged diameter portion 31 side of the sleeve 30. The thread 41 is inserted, and the connector main body 20 is disposed at an appropriate position of the metal wire trunk thread 41. Thereafter, the sleeve 30 is moved toward the one end 23 side of the connector main body 20 with a strong force. Thereby, the metal wire trunk yarn 41 is fixed to the first taper portion 22.
The connection procedure between the connector main body 20 and the metal wire trunk thread 41 is thus completed.

Next, a Harris connecting step of connecting the metal wire Harris 42 to the connector main body 20 is performed. In this step, first, the connector main body 20 is inserted into the sleeve 30 from the other end 25 so that the enlarged diameter portion 31 of the sleeve 30 is disposed on the other end 25 side of the connector main body 20. At this time, the connector main body 20 is inserted while the maximum diameter portion 24 b is in contact with the inner wall of the main body portion 32 of the sleeve 30. Thereafter, the sleeve 30 is disposed around the minimum diameter portion 24 a or the small diameter portion 21. At this time, a gap into which the metal wire Harris 42 can be inserted is formed between the inner wall of the sleeve 30 and the shaft of the connector main body 20.
Next, as shown in FIG. 5B, the metal wire is inserted into the gap between the inner wall of the sleeve 30 and the shaft of the connector main body 20 from the other end 25 side of the connector main body 20, that is, from the enlarged diameter portion 31 side of the sleeve 30. The Harris 42 is inserted, and the end 42b of the metal wire Harris 42 is positioned near the minimum diameter portion 24a. Thereafter, the sleeve 30 is moved to the other end 25 side of the connector main body 20 with a strong force by applying momentum. Thereby, the metal wire Harris 42 is fixed to the taper portion 24.

Then, if the tip 42b side of the metal wire Harris 42 seems to protrude from the sleeve 30 for a long time, the metal wire Harris 42 is cut out to obtain the state shown in FIG. The connection procedure between the connector main body 20 and the metal wire Harris 42 is thus completed.
Since it is not easy to carry the device using the metal wire main thread 41 and the metal wire Harris 42, it is preferable that the main thread connecting step and the Harris connecting step are performed at a fishing spot. In addition, the trunk line connection process may be performed before moving to the fishing spot, the metal wire trunk thread 41 to which the connector main body 20 is connected may be brought into the fishing spot, and only the Harris connection process may be performed at the fishing spot.
When manufacturing the device S including a plurality of metal wire Harris 42, the trunk thread connecting step is continuously performed as many times as necessary to connect the necessary number of connector main bodies 20 to appropriate portions, and then each of the connector main bodies 20 is connected. The Harris connecting step of connecting the metal wire Harris 42 is continuously performed the same number of times. Note that the trunk yarn connecting step and the Harris connecting step may be alternately repeated as many times as necessary.
Thus, the fishing device S of FIG. 1 in which the connecting portions are configured as shown in FIG. 2 is completed.

In addition, although the connector main body 20 of this embodiment comprises the 1st taper part 22 and the 2nd taper part 24 in the same shape and magnitude | size, the largest diameter part of 1st taper part 22 'is shown. It is good also as a connector main body 20 '(not shown) comprised so that the diameter of the largest diameter part 24b' of 2nd taper part 24 'may become thick about 0.05-0.1 mm rather than the diameter of 22b'. At this time, the inner diameters of the main body portions 32 of the pair of sleeves 30 are configured to have substantially the same diameter as the maximum diameter portion 22b ′ of the first tapered portion 22 ′ formed to be thin.
The connector main body 20 ′ thus configured is suitable when a thin metal wire Harris 42 is used or when a thin resin fishing line or a synthetic or natural fiber fishing line is used instead of the metal wire Harris 42.

When the connector main body 20 ′ thus configured is used, the sleeve placement step is performed before the trunk yarn connection step.
In the sleeve placement step, first, a linear connector main body 20 ′ is used in the same manner as the connector main body 20 of FIG. 3, and the diameter-expanded portion 31 is formed from one end 23 ′ on the side of the first tapered portion 22 ′ formed thin. The connector main body 20 ′ is inserted into the sleeve 30 so that is disposed on the other end 25 ′ side.

Next, the connector main body 20 ′ is bent at the small diameter portion 21 ′ to obtain the state shown in FIG. 6 and the sleeve placement step is completed. Thereby, the sleeve 30 is disposed within a range sandwiched between the bent portions of the maximum diameter portion 24b ′ and the small diameter portion 21 ′, and can move only within this range. That is, since the maximum diameter portion 24b ′ of the second taper portion 24 ′ is formed to be thicker than the inner diameter of the main body portion of the sleeve 30, the sleeve 30 is limited to the maximum diameter portion 24b ′ and has one end 23 ′ and the other end 25. It will not fall out of any of the ´s.
If this sleeve placement step is performed in advance before moving to the fishing spot, the Harris connecting step at the fishing spot can be shortened in time, which is preferable.
Since the other structure of the connector main body 20 ′ and the other procedure for producing the fishing device S using the connector main body 20 ′ are the same as those of the connector main body 20, description thereof will be omitted.

Moreover, you may use the grooved bead 34 shown in FIG. 7 as a cylindrical body member instead of the sleeve 30 of this embodiment. 7A is a side view of the bead 34, and FIG. 7B is a cross-sectional view taken along line AA in FIG. 7A.
The beads 34 are made of a synthetic resin such as an ABS resin, and are formed in a substantially ring shape having communication holes 34a as shown in FIG. At one end of the bead 34 in the axial direction, an enlarged diameter portion 34b is formed which is cut out into a substantially conical shape coaxial with the bead 34 and whose inner diameter extends in a funnel shape toward one end of the bead 34. A groove portion 34c extending in the axial direction of the bead 34 from one end to the other end is formed.
In the step of connecting the metal wire Harris 42 to the connector main body 20 using the grooved beads 34, Harris is provided except that the beads 34 are arranged so that the enlarged diameter portion 34 b is arranged on the other end 25 side. It is the same as a connection process, and it connects as shown in FIG.
FIG. 8 is an explanatory view showing a state in which a non-metallic trunk thread 43 is connected to the connector main body 20 by a bundling and elastic tube 33, and a metal wire Harris 42 is connected using a bead 34. The connection part of the thread | yarn 43 is partially shown with sectional drawing.

  Since the beads 34 are made of synthetic resin, the friction resistance between the beads 34 and the metal wire is increased, the metal wires are less likely to slip between the inner walls of the beads 34, and the metal wire trunk yarn 41 and the metal wire Harris 42 are stronger. It can be held. The beads 34 are made of a synthetic resin and need a thickness to obtain a pressing force for fastening the first and second taper portions 22 and 24. Therefore, the wall portion is thicker than the sleeve 30, and the whole However, since the connecting portion between the trunk thread and Harris is separated from the fish predation position, there is little hindrance to predation and there are few demerits due to thickness. Furthermore, since the enlarged diameter part 34b is expanding toward the side into which the metal wire Harris 42 is inserted, the metal wire Harris 42 can be easily inserted. Since the enlarged diameter portion 34b is expanded in the same direction as the second tapered portion 24 is expanded, when a force is applied to the metal wire Harris 42, the inner wall of the expanded diameter portion 34b of the bead 34 and the second tapered portion 24 are expanded. And the connection force between the bead 34 and the second taper portion 24 can be increased.

The groove portion 34 c has an anti-slip effect that prevents a finger from slipping on the surface of the bead 34 when the bead 34 is twisted and fixed to the second tapered portion 24. The Harris connection process using the beads 34 can be easily performed in less than 1 minute per location without using tools and taking into account the accompanying actions.
By using ABS resin as the material of the bead 34, the bead 34 can be configured to have a certain degree of viscosity, elasticity, and appropriate hardness suitable for holding and holding the metal wire Harris 42. It is difficult to move around 24, the Harris connecting process is simple, and it is possible to make it difficult for the metal wire Harris 42 to come off after the connection.

Moreover, in this embodiment, the metal wire trunk yarn 41 is used as the trunk yarn, and the metal wire trunk yarn 41 is connected to the connector main body 20 by the sleeve 30, but a non-metallic system such as a resin fishing line, a natural or synthetic fiber fishing line, or the like. When the trunk yarn 43 is used, the non-metallic trunk yarn 43 may be directly tied to the first tapered portion 22 by a known method such as the method described in the specification of Japanese Patent No. 3540284. Moreover, as shown in FIG. 8, the elastic tube 33 which covers so that the non-metallic trunk thread 43 may be tied directly to the 1st taper part 22, and the tied part may be clamp | tightened may be covered.
If the elastic tube 33 is covered as shown in FIG. 8, the fishing device S is less likely to be entangled, which is preferable. Further, by using a color tube for the elastic tube 33, a fish collection effect can be obtained depending on the fish type.
In addition, when the elastic tube 33 is not covered, the tangling of the fishing device S can be prevented by configuring the length from the maximum diameter portion 22b of the first tapered portion 22 to the one end 23 to be short.

  When the non-metallic trunk thread 43 is directly connected to the first taper portion 22, in the procedure for manufacturing the fishing device S, the specification of Japanese Patent No. 3540284 is described in the first taper portion 22 instead of the trunk thread connecting step. The non-metallic trunk thread 43 is directly connected to the first taper portion 22 by a known method such as the above method, and the connector main body 20 is inserted into the elastic tube 33 from the one end 23 side as necessary. The process of covering so that the range to the part which the diameter part 21 bent is carried out is performed.

Further, in the case of using a non-metallic trunk thread 43 and a non-metallic Harris 44 such as a resin fishing line, a natural or synthetic fishing line instead of the metallic trunk thread 41 and the metallic wire Harris 42, as shown in FIG. It is preferable to use beads 34 instead of the sleeve 30.
The synthetic resin bead 34 is used when a non-metallic fishing line is sandwiched and fixed between the metal connector main body 20 and the metal sleeve 30 as shown in FIG. This is because when a strong force is applied, the fishing line is flattened (like udon) and slips through between the connector main body 20 and the sleeve 30. Since a 1 kg fish is about 40 cm, a sleeve 30 can be used as shown in FIG. 2 for smaller fish such as kawahagi, white geese, and fowl.

The connector main body 20a of FIG. 9 is formed such that the distance between the end 23 and the maximum diameter portion 22b is long, and the space from the end 23 to the beads 34 can be covered with an elastic tube 35. It should be noted that the non-metallic trunk thread 43 is connected by the beads 34 using the connector main body 20 in which the distance between the end portion 23 and the maximum diameter portion 22b is not long so that the elastic tube 35 is not covered. May be.
By covering the space from the end 23 to the bead 34 with the elastic tube 35, the nonmetallic trunk thread 43 can be more strongly fixed to the connector main body 20a.

As shown in FIG. 9, in the trunk thread coupling step when the nonmetallic trunk thread 43 is coupled to the connector main body 20 a using the beads 34 and the elastic tube 35, first, the diameter-expanded portion 34 b of the beads 34 is coupled. The connector main body 20a is inserted into the bead 34 from the one end 23 so as to be disposed on the one end 23 side of the tool main body 20a. The beads 34 are arranged around the minimum diameter portion 22a or the small diameter portion 21.
Next, after inserting the nonmetallic trunk thread 43 into the gap between the enlarged diameter portion 34b of the bead 34 and the shaft of the connector main body 20a and passing it to the other end side of the bead 34, the beads in the nonmetallic trunk thread 43 The beads 34 are positioned at 34 final positions. The nonmetallic trunk thread 43 is inserted into the gap between the enlarged diameter portion 34b of the bead 34 and the shaft of the connector main body 20a again. As a result, a ring of the nonmetallic trunk thread 43 that makes a round around the wall of the bead 34 is formed, so that the outer side of the bead 34 is pulled while pulling the end of the nonmetallic trunk thread 43 on the side of the enlarged diameter portion 34b. The non-metallic trunk thread 43 exposed to is inserted into the groove 34c.

The procedure for inserting the nonmetallic trunk thread 43 into the gap between the enlarged diameter portion 34b of the bead 34 and the shaft of the connector main body 20a may be repeated to wind around the wall of the bead 34 two or more times. The number of times of winding is preferably 1 to 2 times.
Thereafter, the beads 34 are moved toward the one end 23 side of the connector main body 20a with a strong force. Thereby, the nonmetallic trunk yarn 43 is fixed to the first taper portion 22.
The connector main body 20 a is inserted into the elastic tube 35 from the one end 23, and the elastic tube 35 is mounted on the part from the end 23 side end of the bead 34 to the one end 23.
The connection procedure between the connector main body 20a and the non-metallic trunk thread 43 is thus completed.

As shown in FIG. 9, in the Harris connecting step in which the nonmetallic Harris 44 is connected to the connector main body 20 a using the beads 34, the nonmetallic Harris 44 to which the fishhook 50 has been connected in advance is used. . The non-metallic Harris 44 is formed 7 to 10 cm longer than the Harris length required for the fishing device S for easy work.
In the Harris connecting step, first, the connector main body 20a is inserted into the bead 34 from the other end 25 so that the enlarged diameter portion 34b of the bead 34 is located on the other end 25 side of the connector main body 20a. The beads 34 are arranged around the minimum diameter portion 24 a or the small diameter portion 21.

Next, a non-metallic Harris 44 is inserted into the gap between the enlarged diameter portion 34b of the bead 34 and the shaft of the connector main body 20a from the end portion 44b and passed to the other end side of the bead 34. The bead 34 is positioned at a position that leaves the required length. The non-metallic Harris 44 is again inserted from the end 44b into the gap between the enlarged diameter portion 34b of the bead 34 and the shaft of the connector main body 20a. This forms a ring of non-metallic Harris 44 that goes around the wall of the bead 34, so that the non-metallic metal exposed to the outside of the bead 34 while pulling the end 44 b of the non-metallic Harris 44. The system Harris 44 is inserted into the groove 34c.
The procedure of inserting the non-metallic Harris 44 into the gap between the enlarged diameter portion 34b of the bead 34 and the shaft of the connector main body 20a may be repeated to wind around the wall of the bead 34 two or more times. The number of times of winding is preferably 1 to 2 times.
Thereafter, the beads 34 are moved to the other end 25 side of the connector main body 20a with a strong force. Thereby, the nonmetallic Harris 44 is fixed to the second taper portion 24. The end portion 44b of the non-metallic Harris 44 is cut at a position left by about 1 to 1.5 cm from the bead 34, and the connecting procedure between the connector main body 20a and the non-metallic Harris 44 is completed.

As described above, the non-metallic trunk thread 43 and the non-metallic Harris 44 are wound around the wall of the bead 34 and held by the groove 34c, and are sandwiched between the bead 34 and the connector main body 20a. The movement of the beads 34, the non-metallic stem yarn 43, and the non-metallic Harris 44 in the direction along the connector main body 20 a is prevented, and the non-metallic stem yarn 43 and the non-metallic Harris 44 are connected by the connector main body 20 a. Is possible.
Further, after winding the nonmetallic trunk thread 43 around the wall of the bead 34, the nonmetallic trunk thread 43 is sandwiched and fixed between the bead 34 and the connector main body 20a. Since the trunk thread 43 is not tied, the connecting position of Harris in the fishing device S can be freely changed.

  Since the end 44b of the non-metallic Harris 44 is disposed at a position left about 1 to 1.5 cm from the bead 34, the non-metallic Harris 44 is extended 1 to 1.5 cm from the bead 34 when the non-metallic Harris 44 is replaced. By holding the end 44b and the connector main body 20a together and pushing the bead 34 toward the minimum diameter portion 24a, the bead 34 can be easily moved toward the minimum diameter portion 24a and the non-metallic Harris 44 can be loosened. The non-metallic Harris 44 can be easily replaced. Note that the end 44b is in a position where the non-metallic Harris 44 is not easily entangled, and does not cause entanglement.

In FIG. 9, the non-metallic Harris 44 is wound around the bead 34 to connect the non-metallic Harris 44 to the connector main body 20a. However, as shown in FIG. The metal wire 45 may be tied to the end opposite to the fishhook 50 via the bead 36, and the end of the metal wire 45 may be connected to the connector main body 20a by the bead 34. With this configuration, it is not necessary to wind the non-metallic Harris 44 around the beads 34, and the non-metallic Harris 44 can be easily connected to the connector main body 20a at the fishing spot in the same manner as the metal wire Harris 42. Can be linked to.
The beads 36 are known beads made of a substantially cylindrical body made of plastic.

In connecting the non-metallic Harris 44 and the metal wire 45, first, the non-metallic Harris 44 and the metal wire 45 are passed through the beads 36 together. Only the metal wire 45 is folded in half at a position adjacent to the bead 36, and a non-metallic Harris 44 is connected to the periphery of the folded portion by a known method, so that the non-metallic Harris 44 and the metal wire 45 are connected. Complete the consolidation.
Since the bead 36 is sandwiched between the two folded portions, the bead 36 side is thick and the reverse side of the bead 36 is thin. In other words, even when the non-metallic Harris 44 is pulled, the bead 36 side in the pulling direction is thick, so that the non-metallic Harris 44 is locked at the portion gradually thickening toward the bead 36 side. Is done.
Since the non-metallic Harris 44 and the metal wire 45 are inserted through the beads 36, the non-metallic Harris 44 and the metal wire 45 can be placed on a continuous line.

8 and 9, the metal wire Harris 42 or the non-metallic Harris 44 is connected by the connector main body 20 and the beads 34. As shown in FIG. 11, the squid angle 56 in which the beads 34 are integrally embedded is shown. You may connect with the connector main body 20 directly. The bead 34 is fixed to the squid angle 56 so that the enlarged diameter portion 34b is located on the needle tip 56a side, that is, on the opposite side of the connector main body 20.
At the time of connection, if a metal wire fishing line (not shown) is sandwiched between the connector main body 20 and the beads 34, the connector main body 20 and the squid angle 56 can be firmly fixed.
In FIG. 11, the bead 34 is embedded in the squid angle 56, but the bead 34 is embedded in another fishing gear such as a lure, minnow, squid, etc., and connected to the connector main body 20 in the same manner as in FIG. You may do it.

Further, the balance 60 of FIG. 12 may be configured by forming a long portion from the bent portion of the small-diameter portion 21 of the connector main body 20 of the above embodiment to the one end 23.
The balance 60 of FIG. 12 is formed of a substantially cylindrical rod-like body having a small diameter portion 61 at the center, a first taper portion 62 at both ends, and a second taper portion 64, and ends from the bent portion of the small diameter portion 61. The structure is the same as that of the connector main body 20 of FIGS.
The balance 60 is bent at the small diameter portion 61, the non-metallic trunk thread 43 is connected to the first taper portion 64 in the same manner as in FIG. 8, and the metal wire Harris 42 is connected to the second taper portion 64. Has been. Further, a weight (not shown) is connected to the tip of the nonmetallic trunk thread 43 extending from the first taper portion 62. A non-metallic Harris 44 may be connected to the second tapered portion 64 instead of the metal wire Harris 42.
Since the balance 60 is configured as described above, the portion from the bent portion of the small-diameter portion 61 to the one end 63 becomes a ridge, and a weight (not shown) is connected to the lower end of the non-metallic trunk thread 43. A fulcrum, a force point, and an action point are formed, and the metal wire Harris 42 is connected to the second taper portion 64 so as to function as an insulator balance.

S fishing device 1 road thread 2 trunk thread 3 Harris 5 fishhook 6 salkan 7 weight 8 fishing rod 9 reel 10 fishing line connector (connector)
20, 20 ', 20a Connector main body 21, 61 Small diameter portion 22, 22', 62 First taper portion 22a, 24a Minimum diameter portion 22b, 24b, 22b'24b 'Maximum diameter portion 23, 23', 63 One end 24, 24 ', 64 Second taper portion 25, 25' Other end 30 Sleeve 31, 34b Expanded diameter portion 32 Main body portion 33, 35 Elastic tube 34, 36 Bead 34a Communication hole 34c Groove portion 40, 45 Metal wire 41 Metal wire Stem yarn 42 Metal wire Harris 42a Tip 43 Non-metal stem yarn 44 Non-metal Harris 44b End 50 Fishing hook 51a Needle tip 51b Bend 52 Needle barrel 53 Taper 53a Minimum diameter 53b Maximum diameter 54 Rear end 56 Squid Angle 60 Balance 101 Metal wire 102, 103 Side 104 Harris 105 Clamping stop 106 Introduction port 107 Trunk thread 108 Ring mounting part 109 Automatic Harris stop 11 Beads 111 stem threading for standing facing holes 112 knots 113 knot ball 115 hook

Claims (10)

A fishing line connector for connecting a plurality of fishing lines to each other,
A connector main body having a first connecting portion for connecting the first fishing line on one end side and a second connecting portion for connecting the second fishing line on the other end side, and the first and second connections A cylindrical member disposed around at least one of the parts,
The connecting portion is a portion from the thickest maximum diameter portion provided at a predetermined position on the end side of the connector main body to the thinnest minimum diameter portion located on the opposite side of the end portion from the maximum diameter portion. Is formed in a substantially circular cross section, and has a tapered shape in which the diameter gradually decreases from the maximum diameter portion to the minimum diameter portion,
The cylindrical member is formed of a substantially cylindrical body having an inner diameter that is substantially the same as the maximum diameter portion, and the inner diameter is large at an end located on the maximum diameter portion side when arranged around the coupling portion. With an enlarged diameter part
The fishing line corresponding to the at least one connecting portion is sandwiched between at least one of the first and second connecting portions and the cylindrical member, and the at least one connecting portion and the corresponding fishing line are sandwiched. And the fishing line corresponding to the connecting portion where the cylindrical member is not arranged is connected to the connecting portion where the cylindrical member is not arranged. Thereby, the first fishing line and the second fishing line are coupled to each other via the coupling body. The first fishing line is a trunk thread,
The second fishing line is Harris made of a metal wire,
At least one of the first and second connection parts is the second connection part, and the connection part where the cylindrical member is not disposed is the first connection part,
The fishing line connector according to claim 1, wherein the cylindrical member is made of metal. The first fishing line is a trunk thread;
The second fishing line is a Harris composed of a non-metallic Harris or a metal wire whose main component is at least one material among a group including synthetic resin, natural fiber, and synthetic fiber,
At least one of the first and second connection parts is the second connection part, and the connection part where the cylindrical member is not disposed is the first connection part,
The cylindrical member is made of synthetic resin, and includes a groove portion extending in an axial direction of the cylindrical member on an outer surface, and the groove portion is a portion of the Harris wound around the wall of the cylindrical member. The fishing line connector according to claim 1, wherein a portion disposed outside the cylindrical member can be stored.   2. The fishing line according to claim 1, wherein the connector main body includes a straight rod-shaped body that is not bent or a rod-shaped body that is bent between the first connecting portion and the second connecting portion. Coupling tool. Via the fishing line connector provided with a connector main body having a first connecting part for connecting the trunk thread on one end side and a second connecting part for connecting the metal wire Harris on the other end side, A fishing line connection method for connecting the metal wire Harris,
The connecting portion is a portion from the thickest maximum diameter portion provided at a predetermined position on the end side of the connector main body to the thinnest minimum diameter portion located on the opposite side of the end portion from the maximum diameter portion. Is formed in a substantially circular cross section, and has a tapered shape in which the diameter gradually decreases from the maximum diameter portion to the minimum diameter portion,
A trunk yarn connecting step of connecting the stem yarn to the first connecting portion;
The connector main body is inserted into a cylindrical member having an inner diameter substantially the same as the maximum diameter portion of the second connecting portion, and the diameter of the connecting member main body is smaller than the inner diameter of the cylindrical member. A cylindrical member insertion step of disposing the cylindrical member around a position having;
A Harris insertion step of inserting the metal wire Harris from the end on the second connection portion side and disposing it in a gap between the connector main body and the cylindrical member,
While holding the metal wire Harris between the cylindrical member and the connector main body, the cylindrical member is moved to the maximum diameter portion side of the second connecting portion, and the metal wire Harris is moved. A fishing line connecting method, comprising: a metal wire Harris connecting step of connecting the cylindrical body member and the second connecting portion to connect to the connector main body. Before the cylindrical member insertion step,
A needle tip portion on the front end side, a needle barrel portion on the rear end side provided continuously and integrally with the needle tip portion, and the most provided in a predetermined position on the rear end side of the needle barrel portion The portion from the thickest maximum diameter part to the thinnest minimum diameter part located on the needle tip side from the maximum diameter part is formed in a substantially circular cross section, and from the maximum diameter part to the minimum diameter part, A taper portion having a tapered shape with a gradually decreasing diameter, and the needle barrel portion of the fishing hook is inserted into the cylindrical body member, and the diameter of the needle barrel portion is smaller than the inner diameter of the cylindrical body member. Arranging the cylindrical member around a position having:
Inserting the metal wire Harris from the rear end, and disposing in the gap between the cylindrical body member and the needle body portion;
While holding the metal wire Harris between the cylindrical body member and the needle body portion, the cylindrical body member is moved to the maximum diameter portion side of the taper portion, and the metal wire Harris is moved to the taper portion. A fishhook connecting step of connecting the metal wire Harris to the fishhook by being sandwiched between the cylindrical member,
And
After the metal wire Harris connecting step, while holding the metal wire Harris between the cylindrical member and the connector main body, the cylindrical member is moved to the minimum diameter portion side to move the metal wire Harris. After the connection state between the second connection portions is loosened and the metal wire Harris is moved in the circumferential direction of the connector main body, the needle tip portion is adjusted so as to face upward of the fishing device. The step of correcting the direction of the tip portion of the fishing hook is performed by moving the cylindrical member to the maximum diameter portion side of the second connecting portion and fixing it again. The fishing line connecting method according to claim 5. A non-metallic Harris having a first connecting portion for connecting a trunk thread on one end side and having at least one material as a main component in a group including synthetic resin, natural fiber, and synthetic fiber on the other end side A fishing line connecting method for connecting the stem thread and the non-metallic Harris through a fishing line connector having a connector main body having a second connecting part for connecting
The connecting portion is a portion from the thickest maximum diameter portion provided at a predetermined position on the end side of the connector main body to the thinnest minimum diameter portion located on the opposite side of the end portion from the maximum diameter portion. Is formed in a substantially circular cross section, and has a tapered shape in which the diameter gradually decreases from the maximum diameter portion to the minimum diameter portion,
A trunk yarn connecting step of connecting the stem yarn to the first connecting portion;
The connector main body is inserted into a cylindrical member having an inner diameter substantially the same as the maximum diameter portion of the second connecting portion, and the diameter of the connecting member main body is smaller than the inner diameter of the cylindrical member. A cylindrical member insertion step of disposing the cylindrical member around a position having;
A Harris insertion step of inserting the non-metallic Harris from an end portion on the second coupling portion side and disposing it in a gap between the coupling body and the cylindrical member,
The non-metallic Harris that has passed through the gap between the connector main body and the cylindrical member is inserted at least once more from the end on the second connecting portion side, and around the wall of the cylindrical member. A portion of the non-metallic Harris that is disposed outside the wall of the cylindrical member is wound on the outer surface of the cylindrical member in the axial direction of the cylindrical member. Storing in a groove carved to extend; and
While holding the non-metallic Harris between the cylindrical member and the connector main body and in the groove, the cylindrical member is moved to the maximum diameter portion side of the second connecting portion. A fishing line coupling comprising: a non-metallic Harris coupling step of coupling the non-metallic Harris to the coupling body by sandwiching the non-metallic Harris between the cylindrical member and the second coupling portion. Method. Prior to the cylindrical member insertion step, performing a step of connecting the non-metallic Harris to a fishing hook,
After the non-metallic Harris connecting step, the cylindrical member is moved to the minimum diameter portion side while holding the non-metallic Harris between the cylindrical member and the connector main body and in the groove portion. By loosening the connection state between the non-metallic Harris and the second connecting portion and moving the non-metallic Harris in the circumferential direction of the connector body, the tip of the fishhook is used for the fishing After adjusting so as to face upward of the mechanism, the cylindrical member is moved again to the maximum diameter portion side of the second connecting portion and fixed, thereby correcting the direction of the needle tip portion. The fishing line connecting method according to claim 7, wherein the step is performed. A fishing device comprising a trunk thread and Harris having an end connected to the trunk thread via a fishing line connector,
The fishing line coupler has a first coupling part for coupling the trunk thread on one end side and a second coupling part for coupling the Harris on the other end side, the first and the first A cylindrical member disposed around at least one of the two connecting portions, and
The connecting portion is a portion from the thickest maximum diameter portion provided at a predetermined position on the end side of the connector main body to the thinnest minimum diameter portion located on the opposite side of the end portion from the maximum diameter portion. Is formed in a substantially circular cross section, and has a tapered shape in which the diameter gradually decreases from the maximum diameter portion to the minimum diameter portion,
The cylindrical member is formed of a substantially cylindrical body having an inner diameter that is substantially the same as the maximum diameter portion, and the inner diameter is large at an end located on the maximum diameter portion side when arranged around the coupling portion. With an enlarged diameter part
The stem yarn or Harris corresponding to the at least one of the connecting portions is sandwiched between at least one of the first and second connecting portions and the cylindrical body member, whereby the at least one of the at least one of the first and second connecting portions. When there is a connecting portion to which the corresponding trunk yarn or Harris is connected and the cylindrical member is not disposed, the cylindrical member is disposed in the connecting portion where the cylindrical member is not disposed. A fishing device characterized in that the stem yarn and Harris are connected via the connector main body by connecting the stem yarn or Harris corresponding to a connecting portion where no is arranged. Further comprising a fishhook coupled to the Harris;
The Harris consists of a metal wire,
The fishhook has a tip end on the front end side, a needle end portion on the rear end side provided continuously with the needle tip portion, and a predetermined position on the rear end side of the needle barrel portion. A portion from the thickest maximum diameter portion provided to the thinnest minimum diameter portion located on the needle tip side from the maximum diameter portion is formed in a substantially circular cross section, and the maximum diameter portion to the minimum diameter A taper part having a tapered shape with a gradually decreasing diameter over the part,
The fishhook is connected to the metal wire by sandwiching the metal wire between the tapered portion and the cylindrical member made of a substantially cylindrical body having an inner diameter substantially the same as the maximum diameter portion. The fishing device according to claim 9, wherein the device is a fishing device.

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