KR200186624Y1 - Electrically illuminable fishing float - Google Patents

Abstract

It is an electroluminescent fishing bobber which emits light as a battery by forming a conductive layer on the jig saw itself. The present invention is a fishing bobber consisting of a float floating in the water, a bobbin pole attached to the upper part of the bobbin, and a bobbin attached to the lower part of the bobbin body. The coated inner insulating layer, the outer conductive layer formed on the inner insulating layer, and the outer insulating layer coated on the outer conductive layer are constituted. The LED is bonded to the top of the jigsaw, one terminal is connected to the inner conductive layer of the jigsaw, the other terminal is connected to the outer conductive layer, and the battery is connected to the inner and outer conductive layer at the bottom of the jigsaw, There is an electroluminescent fishing bobber, characterized in that the bottom of the jigsaw, and the protective cap to protect the battery is formed, forming a bobbin body with the protective cap.

Description

Electrically illuminable fishing float

The present invention relates to a fishing bobber, and relates to a fishing bobber that electrically emits light so that the quality of the fish can be easily seen at night.

Fishing bobbers float at the right level above the surface of the water and must be sensitive to the quality of the fish's mouth and must be made to stand out from a distance. Therefore, the shape and material of the bobber is one of the most important considerations in fishing.

The structure of a general fishing bobber is described with reference to FIG. In Fig. 1, the bobber is composed of a float body (1), a float floating in the water, a bobbin pole (3) extending long over the bobbin body (1), and a bobbin leg (5) long attached to the bottom of the bobbin body (1). do. At the end of the tail (5) is connected to the tail of the fabric (7) made of weaving straps that can flow smoothly to secure the bobber to the fishing line.

Here, the bobbin body (1) should have a buoyancy enough to rise to the appropriate height above the surface of the floats (3) floating on the water. The tip of the claw saw (3) is always above the surface of the water and swings up and down depending on the quality of the fish, the tip of the claw saw is called a jjigae. The tail leg (5) serves to align the center of gravity with the claw saw (1) in order to make the tail body (3) standing upright in the water, may be formed integrally with the tail body (3) or may be manufactured separately and attached. do.

On the other hand, in order to see the movement of the magnifier in the dark when fishing at night, a conventional chemi-light containing a phosphorescent (aka, luminous) is used to attach to the tip of the magnifier. Chemilite contains phosphorescent chemicals in a cylindrical tube of about 20-30mm in length and about 2-5mm in diameter, and is widely used because it has the advantage of making night fishing easier.

However, Chemie Lite weighs 150mg and has a volume of 0.16ml (based on the diameter of 3mm Chemie Lite), which greatly affects the buoyancy of the bobber. The bobber is sensitive to this small weight and changes its position. That is, since the conventional buoyancy has been determined and produced the optimum buoyancy for daytime, there is a problem that the buoyancy of the fishing bobber is different from the optimum value because it is attached to the chemistry separately for the night.

In order to solve this problem, fishing bobbers that emit light by constructing electric circuits using batteries and LEDs have appeared. The float's buoyancy is optimized to include the battery, LED, and wiring weight, resulting in a consistent float during the day or night. Just turn on the LEDs at night.

The structure of the electroluminescent bobber currently used will be described with reference to FIG.

One terminal of the LED 13 is bonded to the end of the known carbon saw 11, i.e., the portion of the carbon saw 11, and the lower end of the carbon saw 11 is in contact with the negative electrode 15a of the battery. Join the negative (-) contact terminal 17 to be. The insulator 19 is covered by the (-) contact terminal 17 to protect it. The battery is a small lithium battery having a diameter of about 4 mm and a length of about 35 mm and having a 3V voltage.

On the other hand, an enamel wire 21 having a diameter of about 0.03 mm is connected to the other terminal of the LED 13 and descends along the peg 11, through a resistor 22, a positive contact attached to the insulator 19. Connect with terminal 23. The positive contact terminal 23 is an electrode in contact with the positive electrode 15b of the battery.

The resistor 22 is used to determine the operating current of the LED 13, and although the resistance of the peg 11 itself is small, it is small to set the allowable operating current of the LED 13 within the rated range. It's a serial part.

The lower end of the carbon peg 11, the (-) contact terminal 17, the insulator 19, the resistor 22, and the (+) contact terminal 23 are protected and waterproofed with a protective cap 25, and the enameled wire ( 21 is coated and protected with a claw saw (11). The LED 13 is coated with a transparent resin 27 to protect the light while dispersing the light.

Protection cap 25 is covered on the upper body 29, the waterproofing function, the rubber packing 31 for fixing the battery is inserted. Therefore, the rubber packing 31 is inserted into the upper interior 33 of the body 29, and the battery is inserted and fixed in the rubber packing 31. When it is not necessary to turn on the LED 13 during the day, the protective cap 25 is opened, and the battery inserted into the rubber packing 31 is reversed, that is, the (-) pole 15a is inserted so as to face the puddle 29. Next, the protective cap 25 may be closed. If the LED 13 is to be turned on, the protection cap 25 may be closed after the battery is inserted as shown in FIG. 2.

Using this bobber, it was possible to turn on the light and fish at night with a consistent buoyancy setting throughout the day and night. However, in this fishing bobber, very thin enameled wire of 0.03mm comes down to the bottom of the sawtooth by riding the outer wall of the sawtower, although it is coated with paint, there is a problem in that it is easily broken or peeled off by external contact. In particular, since the portion covered with the protective cap 25 on the jaw 11 is strongly adhered for waterproofing, damage to the enamel wire 21 becomes more severe.

In addition, because the very thin enameled wire must be handled, the manufacturing process is very inconvenient, requires a lot of labor and increases the defective rate. This is even more so because of the manufacturing problem of fishing bobber, which should reduce the weight other than the bobbin body and the bobbin pole, as the LED and the resistor have very small chip LED and chip resistor. In particular, in order to solder the enamel wire 21 to the LED 13 and the resistor 22, it is necessary to peel off the enamel coating of the enamel wire one by one. In addition, since the resistance must be inserted between the enamel wires in series, the enamel wire 21 must be cut and used in two parts. That is, one part from the resistor 22 to the LED 13 and one part from the resistor 22 to the (+) contact terminal 23 must be worked separately. Stripping, soldering and handling two types of enameled wire of only 0.03 mm in diameter is very inconvenient and low productivity.

Thus, the present applicant solved the conventional problem by forming a conductive layer on the jigsaw itself itself without using a separate enamel wire, and newly devised the shape of the jig itself, maximizing the effect as a fishing bobber.

Accordingly, it is an object of the present invention to provide an electroluminescent fishing bobber which emits light as a battery by forming a conductive layer in a double pole.

1 is an external view of a common fishing bobber.

2 is an exploded view of a conventional light-emitting fishing bobber.

3 is an exploded view of a fishing bobber according to the present invention.

4 is an enlarged view of a portion A of FIG.

5 is a conceptual circuit diagram of the present invention.

6 is an enlarged view of a portion B of FIG.

7 is a part of the manufacturing process of the bobber according to the present invention.

Figure 8: A battery used in the present invention.

9 is an external view of the rubber packing of the present invention.

10 is an external dimension of the fishing bobber according to the present invention.

<Explanation of major symbols in drawings>

Brake stand 11, LED 13, (-) pole 15a, (+) pole 15b, (-) contact terminal 17, insulator 19, enamelled wire 21, resistor 22 ), (+) Contact terminal (23), protective cap (25), transparent resin (27), bobbin (29), rubber packing (31), bobbin (101), bobbin (103), bobbin (105) ), Conductive adhesives 106a and 106b, inner conductive layer 107, inner insulating layer 109, outer conductive layer 111, outer insulating layer 113, LED 115, battery 117, (- Pole 117a, insulator 117b, (+) pole 117c, molding 119, internal contact terminal 121, insulation tube 123, external contact terminal 125, protective cap 127, Rubber packing (129), internal space (131)

Figure 3 is an external view of the electroluminescent bobber according to the present invention. Overall, it consists of a float body 101, which is a floating body floating in the water, a jaw saw 103 extended to the upper portion of the bobbin body 101, and a tail leg 105 attached to the lower portion of the bobbin body 101. It is fishing bobber.

Technical features of the present invention can be seen in the structure of the saw blade 103. 4 and 4A are enlarged views of the portion A of FIG. 3, and the jaw saw 103 may be implemented in two cases. 4, it can be seen that the jaw saw 103 is composed of an inner conductive layer 107, an inner insulating layer 109, an outer conductive layer 111, and an outer insulating layer 113. At present, carbon saws are known. In the present invention, a carbon tooth saw having a diameter of about 0.6 mm is used, and this known tooth saw itself is used as the inner conductive layer 107, and an insulating paint is applied to the inner conductive layer 107 to form an inner insulating layer ( 109 is formed, the conductive coating is applied again to form the outer conductive layer 111, and then the insulating coating is finally applied to form the outer insulating layer 113. Finally, the diameter of the jaw saw 103 formed is about 1mm. Fig. 4A shows a jig of another embodiment. Unlike Fig. 4, a solid 108 of insulating material is used as the inner layer, and an inner conductive layer 107 is coated on the outer surface thereof. That is, in FIG. 4, a carbon saw blade made of a conductor is used, but in FIG. 4A, a low-cost solid bar is used as an inner layer, and an additional inner conductive layer 107 is formed thereon. To make.

The insulating paint applied to the inner insulation layer 109 and the outer insulation layer 113 uses epoxy, lacquer, enamel, and urethane-based varnish. Since the voltage for turning on the LED 115 is low (3V), the insulation strength requirement is weak. Most insulating paints can be used. The coating thickness and the material selection of the insulating paint are arbitrary choices by those skilled in the art. As the conductive paint for forming the outer conductive layer 111 (and the inner conductive layer 107 of Fig. 4A), the inventors mix nickel and carbon. Was used. In order for the LED to turn on efficiently, a current must be supplied as much as the operating current specified in the specification. Therefore, a resistor must be connected in series with the LED. Conventionally, the chip resistors are connected in series as in Fig. 1, but in the present invention, the self-resistance r1 of the conductive paint is used. Thus, there is no need to connect a separate resistor by soldering.

If the weight ratio of nickel to carbon is adjusted to about 99.8: 0.2, the resistance is about 66 kPa. Since the resistance r2 of the carbon saw stand itself is also about 66 kW, the resistance of about 132 kW is connected in series between the LED 115 and the battery 117 as a whole. Therefore, a current of I = V / R = 3V / 132 mA = 22.7 mA can flow, and a current suitable for the operating current of the LED 115 can flow. Since the operating current also varies depending on the type of LED and the emission color, the mixing ratio of nickel and carbon used as the conductive paint is a problem that can be arbitrarily determined by those skilled in the art according to the resistance value to be obtained. In addition, since nickel does not mix and a predetermined | prescribed resistance value comes out only with nickel, and there exists also the resistance r2 of the jaw itself, you may use only nickel as said electroconductive paint. On the other hand, in the case of Figure 4a, since the inner conductive layer 107 and the outer conductive layer 111 is a paint of the same component, the same resistance value will come out, the above forming method is applied as it is.

LED 115 is bonded to the top of the jigsaw 103, one terminal of the LED 115 is connected to the inner conductive layer 107 of the jigsaw 103 and the other terminal is connected to the outer conductive layer 111 Then, the battery 117 is connected to the inner conductive layer 107 and the outer conductive layer 111 at the bottom of the saw blade 103, the LED 115 is turned on. The circuit for this is shown in FIG. In the present invention, the cathode (cathode) of the LED 115 is bonded to the inner conductive layer 107 on the top of the saw blade 103, and the anode (anode) of the LED 115 is bonded to the outer conductive layer 111. The negative electrode of the battery 117 is connected to the inner conductive layer 107 at the bottom of the base 103, and the positive electrode of the battery 117 is connected to the outer conductive layer 111.

As the LED, a very small chip LED is used. Chip LEDs are about 1 ~ 2mm in size, weigh only 0.001g, and have a small current consumption, so they are hardly affected by weight even when used for fishing bobbers, and they also have low battery consumption. The battery 117 uses a commercially available ultra-small lithium battery. It is a very small body having a body length of about 30 mm, a negative electrode length of about 5 mm, and a diameter of about 4 mm, and a voltage of 3 V comes out.

FIG. 6 is an enlarged view of a portion B of FIG. 3 and shows a state in which the inner conductive layer 107 and the outer conductive layer 111 of the jaw saw 103 are connected to each terminal of the LED 115. The cathode of the LED 115 is bonded to the inner conductive layer 107 by the conductive adhesive 106a, and the anode of the LED 115 is bonded to the outer conductive layer 111 by the conductive adhesive 106b. As described above, according to the present invention, since soldering is not performed at the time of joining the LEDs 115, workability is further improved.

After the LEDs 115 are bonded, the whole is molded 119 with a resin such as epoxy FRP. The molding 119 is intended for waterproofing and protecting a role. When the fluorescent pigment is added to the molding resin, the molding 119 emits fluorescence by emitting light from the LED 115, and thus, the visibility is improved.

Referring to Figures 3 and 7 will be described for the contact terminal structure of the bottom of the jaw saw 103. FIG. 7 is a process diagram for manufacturing part C of FIG. 3. 3, the bottom of the jig saw 103, the inner contact terminal 121 connected to the inner conductive layer 107, the insulating tube 123 surrounding the inner contact terminal 121 and the outer conductive layer ( An external contact terminal 125 connected with 111 is attached on the insulator tube 123. See Figure 7.

(A) The lower end structure of the tooth saw stand 103 is formed together with the manufacture of the tooth saw stand 103. First, the inside of the carbon saw stand (finally the inner conductive layer 107) of the starting material is formed inside. The contact terminal 121 is bonded with a conductive adhesive. The internal contact terminal 121 is a spring having a diameter of about 0.8 mm, and is a terminal to which the negative electrode of the battery 117 contacts. If using a solid peg saw as in the case of Figure 4a, the step of applying the inner conductive layer 107 on the solid 108 is added.

(B) After the inner contact terminal 121 is adhered to each other, the insulation tube 123 is covered to completely surround the inner contact terminal 121. The insulator tube 123 guides the negative electrode of the battery 117 to be inserted while protecting the internal contact terminal 121. The insulating tube 123 is equal to or slightly larger than the diameter of the negative electrode of the battery 117. Use a tube of degree.

(C) An internal insulating layer 109 is formed by applying an insulating paint over the insulating tube 123. The internal insulating layer 109 is preferably formed to include a portion of the insulating tube 123 in terms of insulation.

(D) Next, the external contact terminal 125 is covered with the internal insulation layer 109 formed. The external contact terminal 125 is a terminal to which the (+) pole of the battery 117 is in contact, and uses a conical spring to contact the outer diameter of the (+) pole of the battery 117. The large diameter of the conical spring should be about the diameter of the battery 117, and the small diameter of the conical spring should be about the diameter to be inserted into the insulating tube 123.

The form of the battery 117 is as shown in FIG. In Fig. 8, the battery 117 has a negative electrode 117a protruding therein and an insulator 117b around it, and the outer diameter and the entire body become the positive electrode 117c. Accordingly, the negative electrode 117a of the battery 117 enters the insulator tube 123 and contacts the internal contact terminal 121, while the positive electrode 117c of the battery pushes the external contact terminal 125. Contact.

(E) The external conductive layer 111 is formed to cover a part of the external contact terminal 125 while the external contact terminal 125 is inserted into the insulating tube 123. As described above, the outer conductive layer 111 is formed by applying a conductive paint. After the external conductive layer 111 is formed, the external insulating layer 113 is applied. Finally, after the external insulating layer 113 is applied, a heat shrink tube (not shown) is applied to protect the external contact terminal 125. It can also be covered.

Figure 7 is for explaining the concept of a jig structure according to the present invention, the diameter is represented very large compared to the size of the external contact terminal 125, in reality, the diameter of the jig saw is only about 1mm.

When the terminal structure of the bottom of the saw blade 103 is completed through the process of Figure 7, while protecting the entire bottom of the saw blade 103 to cover the protective cap 127 to connect to the body. The shape of the protective cap 127 can be seen in Figure 3, a conical PVC cap is a waterproof treatment to the contact point with the claw saw 103, the lower opening is connected to the bobbin body (101).

It describes the connection structure of the bobbin body 101 and the protective cap 127. The rubber packing 129 is inserted into the upper end of the bobbin body 101 of FIG. The shape of the rubber packing 129 is shown in Figure 9, the inside is empty to accommodate the body of the battery 117, the upper projections (129a, 129b) to be fitted around the lower inner diameter of the protective cap 127 Is formed. Since the protrusions (129a, 129b) and the inner diameter of the lower portion of the protective cap 127 is tight enough to be waterproof, the shape and size of the rubber packing 129 is very important in the present invention. At the lower end of the rubber packing 129, a small tube 129c is formed to accommodate the negative electrode 117a of the battery when the battery is inserted upside down.

Since the fishing bobber according to the present invention is to be used in water, much consideration should be given to waterproof and moisture proofing. As described above, the rubber packing 129 and the protective cap 127 are used to waterproof the terminal and the battery, as well as newly designed the shape of the rubber packing 129. 9, it can be seen that only the upper part of the rubber packing is open and the lower part is completely closed. To turn on the LED and go fishing while turning off the light, open the protective cap 127, remove the battery from the rubber packing 129, and replace the battery 117 so that the (-) pole 117a goes down. At this time, the surface of the battery 117 may be wet. Therefore, according to the present invention, the water buried in the battery is present only in the rubber packing 129 can not affect the body. In the related art, the lower part of the rubber packing is also open, and the water contained in the battery affects the body, causing the body to deform or change in buoyancy.

When the battery 117 is inserted into the rubber packing 129 and the protective cap 127 is inserted, the negative electrode of the battery 117 and the internal contact terminal 121 of the jaw saw 103 come into contact with each other. The positive electrode of 117 and the external contact terminal 125 of the jaw saw 103 come into contact with the LED 115 to light up. If you want to turn off the fire, remove the protective cap 127, and then insert the protective cap 127 to the rubber packing 129 so that the (-) pole of the battery 117 is directed downward. Since the negative electrode of the battery 117 does not come into contact with the internal contact terminal 121 of the jaw 103, the LED 115 does not turn on.

Inside the bobbin body 101 into which the rubber packing 129 is inserted, a space 131 is formed deeper than the small tube 129c of the rubber packing 129, so that the buoyancy of the bobbin body 101 is increased. To increase.

Fishing bobber according to the present invention is characterized in that the electroluminescent type, but in addition, the inventor designed a new shape of the entire fishing bobber itself. Fishing bobber floats perpendicularly to the water, so the top end of the bobbin pole 103 should come out above the water surface at an appropriate height, so the center of gravity and buoyancy design of the entire bobber is very important. Figure 10 shows the design value for the appearance of the fishing bobber according to the present invention.

In the present invention, including the protective cap 127, the bobbin body 101 is formed, the overall shape of the bobbin body 101 forms a shape in which the diameter of the center portion is larger and the diameter becomes smaller toward the top and bottom. That is, there is a point (D) in which the diameter becomes the maximum at the outer diameter of the bobbin body 101, and has a tapered shape in which the diameter decreases toward the upper and lower ends at the maximum diameter point (D), and the upper and lower taper angles are respectively. 10 °.

The ratio of the distance (a) from the top of the protective cap (127) to the maximum diameter point (D) and the distance (b) from the maximum diameter point (D) to the bottom of the tailstock 101 is about (35 to 45): (55 to 65), and is preferably designed in a ratio of 43:57 (that is, a: b = 43: 57).

The distance (c) from the upper end of the jaw saw 103 to the maximum diameter point (D) of the bobbin body 101 is the distance from the maximum diameter point (D) of the bobbin body (101) to the bottom of the leg 105 ( 2 times d) (i.e., c = 2d), and the length e of the jaw saw 103 is designed to be 1 to 1.2 times the length f of the sum of the jaw body 101 and the jaws 105 (i.e., , e = (1 ~ 1.2) f).

This value is such that the center of gravity of the entire bobbin is the maximum diameter point D of the bobbin body 101 with both the battery 117, the saw bar terminals, and the LED 115 attached, and the length of the entire bobbin. Can be modified to an appropriate length as long as it meets the above numerical values.

The bobbin body 101 is made by heat-compressing the hemp (burlap) or germ (sheave) genus. That is, hemp or yam cord is put in a mold molded according to the value of the bobbin body 101 shown in FIG. 10 and compressed to about 130 to 150 ° C. to form a bobbin body, and left at room temperature for 6 hours without being taken out of the mold. To completely remove moisture and dry. This is because, when dried from the outside, the shape of the torso is deformed by moisture. Thus, apply the lacquer sanding sealer (lacquer sanding sealer) about 3 times, apply the oil stencal once, and apply urethane-based varnish twice to the waterproofing body is completed. The hemp and shepherds are used for farming purposes, but they are discarded. Conventionally, the cork body 101 is made using imported cork, but the hemp that is thrown away.

3 is made of a material such as solid (solid), bamboo, carbon, etc., as shown in Figure 1, is attached to the bottom of the body body 101 by an adhesive such as glue.

As described above, according to the present invention, as in the electroluminescent fishing bobber replacing the conventional chemite, since there is no soldering part without using a thin enamel wire, workability and productivity are improved and the defective rate of the final product is improved. There is a deterioration effect. Since there is no chemite, the environmental effect is even greater.

On the other hand, it is possible to make a new body by using hemp or hemp, which is not used by farmers, and it can be a new source of income for farmers. There is no import substitution effect.

Claims (15)

In the fishing bobber consisting of a float that floats in the water, a float that is attached to the upper part of the bobbin for a long length, and a bobbin attached to the lower part of the bobbin, The jig saw consists of an inner conductive layer, an inner insulating layer applied on the upper layer, an outer conductive layer formed on the inner insulating layer, and an outer insulating layer applied on the outer conductive layer, and an LED is bonded to the top of the jigsaw. The terminal is connected to the inner conductive layer of the peg saw, the other terminal is connected to the outer conductive layer, and the battery is connected to the inner and outer conductive layers at the bottom of the peg saw. The upper part of the bobbin body is covered with a protective cap for protecting the battery and the bottom of the bobbin, the electroluminescent fishing bobber, characterized in that forming the bobbin with the protective cap. The inner conductive layer of claim 1 is a carbon band, the inner insulating layer is coated with epoxy, lacquer, enamel or urethane varnish on the inner conductive layer, and the outer conductive layer is made of nickel or a mixture of nickel and carbon. The coating is applied, the outer insulating layer is electroluminescent fishing bobber characterized in that the epoxy, lacquer, enamel, or urethane-based varnish applied to the outer conductive layer. The electroluminescent fishing bobber of claim 2, wherein the weight percentage ratio of nickel to carbon in the conductive paint forming the outer conductive layer is about 99.8: 0.2. The method according to any one of claims 1 to 3, At the bottom of the saw blade, an inner contact terminal connected to the inner conductive layer, an insulated tube surrounding the inner contact terminal, and an outer contact terminal attached to the outer conductive layer attached to the outer conductive layer are attached. A rubber seal in the form of a tube is inserted at the top of the body, so that the first electrode of the battery contacts the internal contact terminal at the bottom of the jig with the battery body inserted into the rubber packing of the body, and the other electrode of the battery contacts the external contact terminal. , A protective cap is covered on the rubber packing electroluminescent fishing bobber, characterized in that to protect the internal contact terminal, the insulation tube, the external contact terminal, the battery and waterproof. In claim 4, The rubber packing is completely sealed except the battery is inserted so that the moisture on the battery does not affect the body, An interior of the bobbin into which the rubber packing is inserted is formed a space other than the space occupied by the rubber packing, thereby increasing the buoyancy of the bobbin. The electroluminescent fishing bobber according to any one of claims 1 to 3, 5, wherein each terminal of the LED is bonded by an inner conductive layer and an outer conductive layer of the tooth saw stand and a conductive adhesive and molded by an epoxy FRP resin. The electroluminescent fishing bobber of claim 4, wherein each terminal of the LED is bonded by an inner conductive layer and an outer conductive layer of the jawsaw and the conductive adhesive and molded by an epoxy FRP resin. The electroluminescent fishing bobber of claim 6, wherein a fluorescent pigment is added to the epoxy FRP resin. The electroluminescent fishing bobber of claim 7, wherein a fluorescent pigment is added to the epoxy FRP resin. In any one of claims 1-3, 5, 7-9, The outer diameter of the bobbin body has a point (D) where the diameter is maximum, and has a tapered shape in which the diameter decreases toward the upper and lower ends at the maximum diameter point (D), and the upper and lower taper angles are 10 °, respectively. The ratio of the distance from the top of the protective cap to this maximum diameter point (D) and the distance from the maximum diameter point (D) to the bottom of the tailstock is about (35 to 45): (55 to 65), The distance from the top of the jaw to the maximum diameter point (D) of the bobbin is twice the distance from the maximum diameter point (D) of the bobbin to the bottom of the tail, An electroluminescent fishing bobber is characterized in that the length of the jigsaw pole is 1 to 1.2 times the length of the bobbin body and the bobbin combined. In claim 4, The outer diameter of the bobbin body has a point (D) where the diameter is maximum, and has a tapered shape in which the diameter decreases toward the upper and lower ends at the maximum diameter point (D), and the upper and lower taper angles are 10 °, respectively. The ratio of the distance from the top of the protective cap to this maximum diameter point (D) and the distance from the maximum diameter point (D) to the bottom of the tailstock is about (35 to 45): (55 to 65), The distance from the top of the jaw to the maximum diameter point (D) of the bobbin is twice the distance from the maximum diameter point (D) of the bobbin to the bottom of the tail, An electroluminescent fishing bobber is characterized in that the length of the jigsaw pole is 1 to 1.2 times the length of the bobbin body and the bobbin combined. In claim 6, The outer diameter of the bobbin body has a point (D) where the diameter is maximum, and has a tapered shape in which the diameter decreases toward the upper and lower ends at the maximum diameter point (D), and the upper and lower taper angles are 10 °, respectively. The ratio of the distance from the top of the protective cap to this maximum diameter point (D) and the distance from the maximum diameter point (D) to the bottom of the tailstock is about (35 to 45): (55 to 65), The distance from the top of the jaw to the maximum diameter point (D) of the bobbin is twice the distance from the maximum diameter point (D) of the bobbin to the bottom of the tail, An electroluminescent fishing bobber is characterized in that the length of the jigsaw pole is 1 to 1.2 times the length of the bobbin body and the bobbin combined. The electroluminescent fishing bobber according to any one of claims 1 to 3, wherein the bobbin body is made of a hemp or bottom liner, paulownia, balsa, and the bobber is made of solid or bamboo or carbon. (New) In claim 1, the inner conductive layer of a tooth saw is coated with a conductive paint composed of nickel or a mixture of nickel and carbon on a solid tooth rest, and the inner insulating layer is epoxy, lacquer, enamel or urethane based on the inner conductive layer. The varnish is applied, and the outer conductive layer is a conductive coating made of nickel or a mixture of nickel and carbon, and the outer insulating layer is coated with epoxy, lacquer, enamel, or urethane-based varnish on the outer conductive layer. Electroluminescent fishing bobber. (New) The electroluminescent fishing bobber according to claim 14, wherein the weight percentage ratio of nickel to carbon in the conductive paint forming the inner conductive layer is about 99.8: 0.2.