WO2009096699A2 - Illumination sensitive fishing float - Google Patents

Abstract

The present invention relates to a fishing float, and more particularly, to a fishing float which illuminates at different brightness intensity levels depending upon the ambient level of illumination. According to one embodiment of the present invention, a light source is mounted to the fishing float such that the fishing float illuminates at a high brightness intensity level when the ambient level of illumination is high and a fish bite is detected and illuminates at a low brightness intensity level and increases its brightness intensity level upon detection of a fish bite when the ambient level of illumination is low. The illumination at a high brightness intensity level is carried out by a xenon lamp or a large volume light emitting diode in cases where the ambient level of illumination is high, whereas the illumination at a low brightness intensity level is carried out by a main light emitting diode. The light source for additional lighting is an auxiliary light emitting diode. The fishing float of the present invention automatically selects a xenon lamp or a light emitting diode in accordance with the ambient level of illumination, and illuminates or flickers at different brightness intensity levels, thereby improving visibility of the fishing float.

Description

Illuminance Responsive Fishing Bobber

The present invention relates to a bobber used for fishing, and more particularly, to a fishing bobber that increases the user's perception according to ambient illumination.

The fishing bobber floats on the water during fishing to allow the user to know the location of the fishing line and to grasp the fine movements of the fishing line, such as the chamfering of the fish and the moment the fish catches the bait. In other words, the fishing bobber informs the movement of the fishing hook with the bait and the fishing line, and thus is a means of judging the relationship between the submerged fish and the fish.

Such fishing bobbers are difficult to observe as the visibility becomes shorter when the ambient light is low, that is, in the case of bad weather even at night or during the day. In addition, in the case of high digging in sea fishing, since the fishing bobber is periodically covered by the floor of the waves, the fishing boat misses the moment to pull the fishing line.

The above fish means a signal that the fishing line is suddenly pulled by the fish to catch the bait, and will be used in the same meaning below.

Therefore, a fishing bobber with light emitting means is used as a means for increasing the recognition power of the bobber in an environment with low ambient light, and in addition, a fishing bobber that detects fishery and informs the angler as a light emitting means is used.

Conventional light emitting means includes a method using a chemical light that emits light by chemical action (Korean Patent Publication No. 10-2003-0066833, Korean Utility Model No. 20-0395191, etc.), and a light emitting diode (LED). ), A light bulb or the like (Korean Utility Model Registration No. 20-0419863, Korean Patent Registration No. 10-0820574, etc.).

In the case of using the camilight, since the weight of the fishing bobber varies depending on whether the camilight is installed, the user has to adjust the weight of the fishing bobber or replace the fishing bobber with a suitable fishing bobber.

On the other hand, in the case of using light emitting means that consumes power, such as a light emitting diode, since the light emitting means is integrally provided in the fishing bobber, the weight of the fishing bobber is kept constant. However, in the related art, since the light emitting means always emits light of the same intensity, there is a problem in that light of the appropriate intensity that the user can easily recognize according to the change in ambient illumination and the presence or absence of fish is not achieved.

In particular, during the day when the height is high, the bobber itself is hidden by the floor of the wave, so that even if the light emitting diode emits light, the user may not observe the emission of the fishing bobber due to the brightness of the surroundings.

On the other hand, considering the case of using at night, there is also a problem that gives a warning to the fish by emitting a certain intensity of light to inform the position of the bobber even when there is no fishing bobber using a conventional camilight or light emitting diode.

Other related data include fishing bobber that emits light by detecting fish in Korean Utility Model No. 20-0396278, Utility Model No. 20-0292616, Japanese Patent No. 2002-095398, and Japanese Patent No. 2004-3104978. There is. In addition, there is a fishing bobber with a light emitting means is disclosed in US Patent Publication No. 20051055272, US Patent No. 5615512, US Patent No. 20050155, US Patent No. 7047687. In addition, there is a U.S. Patent No. 59747721 on a fishing bobber with a high brightness diode.

The present invention has been made to solve the above-described problems, an embodiment of the present invention is to provide a fishing bobber that is emitted by varying the brightness according to the ambient illumination.

In addition, when the ambient illumination is high, the recognition power of the fish is enhanced by high-luminance light emission, and when the ambient illumination is low, it emits light with low brightness to inform the user of the current position of the fish, and when the fishery is detected, it increases the brightness and emits light to the user. The purpose is to make it easier to recognize.

In addition, there is also an object to naturally turn off the power during the fishing process without a separate operation.

In addition, it has the purpose of making it easy to detect fishing fish while having a simple structure, so that even beginners can easily catch fishing.

It also has the purpose of making the detection of the fishery more sensitive.

In addition, even if used for a long time in seawater has the purpose of not shortening the life due to corrosion or the like.

It also has the purpose of enabling the use of a ready-made coin-type battery, the purpose of ensuring sufficient voltage while using the ready-made battery having a certain shape, and the purpose of reliably fixing the coin-type battery.

It also has the purpose of allowing a battery to have a sufficient capacity to be used for a long time.

In addition, there is also an object to facilitate the replacement of the battery.

In order to solve the above problems, the present invention provides a high luminance light emission when the fishery is detected when the ambient illumination is high, and low luminance light emission when the ambient illumination is low, the luminance is lower than the low luminance light emission when the fishery is detected In order to increase the, the illumination response responsive fishing bobber characterized in that the additional light is added as the light source is added.

In addition, the high luminance light emission when the ambient light is high is made of a light of a xenon lamp or a large light-emitting diode, the low luminance light emission when the ambient light is low is made of a light emission of the main light emitting diode, The addition of a light source suggests an illuminance responsive fishing bobber characterized in that it consists of light emission of the auxiliary light emitting diode.

In addition, a magnetic force sensor is provided at the upper portion of the fishery detecting unit, the hollow fishery case, the auxiliary magnet fixed to the inner bottom of the fishery case, and the upper portion of the auxiliary magnet has the same polarity as the upper surface of the auxiliary magnet. Presents the illumination response responsive fishing bobber characterized in that the main magnet is spaced apart from the auxiliary magnet by the repulsive force and is movable up and down.

In addition, the inlet detection unit proposes an illumination response responsive fishing bobber, characterized in that consisting of a capacitive proximity sensor fixed to the inner surface of the body portion.

In addition, the battery proposes the illumination response responsive fishing bobber characterized in that the coin-type battery is fixed to the electric circuit board provided in the middle and the guider formed in the lower side of the body portion.

In addition, the battery has a cylindrical shape in which a first electrode surface is formed on an upper surface thereof, and a hollow cylindrical hole is formed in the center to penetrate up and down, and an inner circumferential surface of the cylindrical hole has a second electrode surface having a polarity opposite to that of the first electrode surface. Presents the illumination response responsive fishing bobber characterized in that.

1 is a cross-sectional view of the irradiance response fishing bobber according to the first embodiment of the present invention.

Figure 2 is a partial cross-sectional view of the roughness response fishing bobber according to the second embodiment of the present invention.

Figure 3 is a cross-sectional view of the irradiance response fishing bobber according to the third embodiment of the present invention.

Figure 4 is an exploded perspective view of the main portion of the rough response responsive fishing bobber shown in FIG.

5 is a perspective view showing another battery of the illuminance-responsive fishing bobber shown in FIG.

Hereinafter, the function, configuration and action of the illuminance-response fishing bobber of the present invention will be described in detail.

According to a preferred embodiment of the present invention, the response response fishing bobber emits high luminance when the fishery is detected when the surrounding illumination is high, and emits the low brightness when the surrounding illumination is low, and when the fishery is detected, In order to increase the brightness, additional light is emitted as a light source is added.

That is, when the ambient illumination is high, that is, during the day of the sunny day, the fishing bobber does not emit light until there is a fisherman, and the position is observed by the naked eye of the user. Inform fish that fishery is detected by fishing bobber.

On the other hand, when the ambient light is low, i.e. at night or during the day, when the weather is cloudy, the fishing bobber emits light at low brightness to indicate the location of the fishing bobber, and when the fishery is detected by the fishing bobber, additional light is emitted to the above emission. This is because the brightness is increased to inform the user that the fishery is a potato by a fishing bobber.

Here, the distinction between high and low ambient light is determined based on the magnitudes of the light intensity values (LUX and LX). In general, the roughness according to the weather conditions is about 10,000 LUX in clear daytime, about 1,000 LUX in daytime with clouds, and about 100 LUX at dusk, and 0.3 LUX on the clear night at full moon. The criteria for determining can be any illuminance value in the range of approximately 200 to 300 LUX. This becomes a reference illuminance previously input to the controller to be described later, and different reference illuminance may be set according to a specific use environment of the fishing bobber.

Hereinafter, the specific configuration and operation of the illuminance response fishing bobber according to the first embodiment of the present invention through the accompanying drawings.

1 is a cross-sectional view of a rough response responsive fishing bobber according to the first embodiment of the present invention.

In the illuminance response type fishing bobber 1 according to the first embodiment of the present invention, the body portion 10 connected to the fishing line 10, the acquisition detection unit 20, the illumination intensity detection unit 30, the light emitting unit 40, a feeling of fishery A branch 50 and a controller 60 are provided.

The body portion 10 is an airtight container with an empty inside, and the body portion includes an upper body 11 made of a transparent material or a translucent material, and a lower body 12 coupled to a lower portion of the upper body.

In this case, in the case of a transparent material it is easy to secure a sufficient visible distance at night, and in the case of an opaque material to prevent glare during the day, it can be used day and night.

At this time, a central cylinder (11a) extending through the upper and lower center of the body portion is formed in the center of the upper end of the upper body 11, the lower body 12 is a cylindrical guider (12a) so that the lower outer peripheral surface of the central cylinder is partially fitted and sealed. ) Is extended upwards. That is, the fishing line passes up and down in the central cylinder (11a) penetrating the body portion 10 is connected to the fishing line and the fishing bobber (1).

At this time, the coupling portion of the upper body 11 and the lower body 12, the coupling portion of the central cylinder (11a) and the guider (12a) may be further provided with a waterproof ring (13) for sealing.

On the other hand, the acquisition detection unit 20 detects whether the fishing bobber 1 is in use and is recovered or retrieved out of the water, and the control unit 60 determines the on / off operation of the fishing bobber. Provides information about

To this end, the inlet detection unit 20 is provided with an inlet detection sensor formed on the exterior of the lower body portion that is submerged in water during normal use. For example, two terminals 21 spaced apart from each other may be provided on the exterior of the lower body, and when a weak current flows through the terminals 21, it may be determined whether the fishing bobber has been obtained by determining whether the current is energized. On the other hand, even when the energization is carried out by measuring a specific resistance value in the water, a method of determining whether or not obtained by comparing with a predetermined resistance value may be used.

On the other hand, the illuminance detection unit 30 is provided on the upper portion of the electrical circuit board (E) coupled to the upper body, is provided with an illuminance measuring sensor for measuring the intensity of the external light incident through the transparent upper body. The ambient illuminance measured by the illuminance measuring sensor is then transmitted to the control unit, whereby the high and low of the ambient illuminance is determined, thereby becoming a selection criterion of the specific light emitting means.

Meanwhile, the light emitting unit 40 includes at least one small xenon lamp 41 and at least two light emitting diodes L.E.D. 42,43 which are provided on the upper part of the circuit board as light emitting means.

That is, the high luminance light emission when the ambient illumination is high and the fishery is detected is made by the xenon lamp 41, and the low luminance light emission and additional light emission when the ambient illumination is low are performed by the light emitting diodes 42 and 43. Light emitting means is selected.

The low luminance, high luminance, and additional light emission of the light emitting means will be described in more detail. First, when the ambient illuminance is high, the controller 60 charges a capacitor (not shown) provided on the electric circuit board E. In the standby state, when the fishery is detected by the fishery detector, the controller causes the xenon lamp 41 connected to the charged capacitor to emit light.

In this case, the very bright light emitted from the xenon lamp allows the user to easily recognize the high brightness light even in the daytime. In addition, even if the fishing bobber is covered by the wave floor during daytime sea fishing, the high brightness of the xenon lamp illuminates the vicinity of the fishing bobber, suggesting that fishes are detected from the surroundings of the waves as compared to the dark blue waves. There is an effect that makes it easy to recognize.

In addition, the light emitting pattern may be formed as a pattern that blinks at a predetermined cycle through a blinking circuit provided in the controller.

In this case, the xenon lamp may be replaced with a large light-emitting light emitting diode having a luminance equal to or greater than that of the xenon lamp.

On the other hand, when the ambient light is low, when the acquisition is detected by the acquisition detector, a part of the light emitting diodes are turned on by the control unit at low luminance.

At this time, in order to control the intensity of light emission, a part of the light-emitting diode (hereinafter, referred to as the main light emitting diode 42) and the remaining light-emitting diode (hereinafter referred to as the auxiliary light emitting diode 43) further lighted according to fishery detection. ) Can be distinguished.

That is, the low luminance light emission of the main light emitting diode 42 is a minimum enough to allow a general user to check the position of the fishing bobber 1 thrown in a low light environment, and selectively adjusts the luminance of the low luminance light emission. To this end, the control unit may be provided with a control means for selecting a portion of the plurality of light emitting diodes, or to change the current value of the pre-selected main light emitting diode.

Meanwhile, the brightness of the main light emitting diode may be automatically adjusted by the controller according to the illuminance measured by the illuminance sensor so as to have a predetermined brightness.

On the other hand, when the fishery is detected by the fishery detector, the additional light emission is made by the auxiliary light emitting diode 43 is emitted by the control unit. That is, the auxiliary light emitting diode 43 additionally emits light in addition to the light emission of the existing main light emitting diode 42, thereby increasing the overall brightness and visually informing the user that the fishery is detected.

In this case, when the attention is low, in the absence of fishery, the intensity of the luminous light is kept low so as not to raise the alertness of the fish, and the position of the fishing bobber can be recognized, and when the fishery is detected, the user is immediately informed of this. It has a recognizing effect.

At this time, the pattern of the additional light emission may be made in a manner of flashing at a predetermined cycle through the above-described flashing circuit, and the main light emitting diodes and the auxiliary light emitting diodes are all flickered, or the auxiliary light emitting diodes 43 are connected to the main light emitting diodes 42. It may be configured to have a different color from). That is, as the light emission pattern is changed to blink or the color is changed, the recognition power of the user is increased.

On the other hand, the fishery detection unit 50 detects a change in magnetic force generated by the movement of the magnetic force generated by the inertia of the magnet provided inside the body portion detects the presence of fishery.

The stopper 53 is provided at the lower portion of the electric circuit board E and fitted to the outer circumferential surface of the guider 12a and the magnetic force sensor 51 positioned at the upper portion of the guider 12. A ring-shaped magnet 52 that can freely move up and down is provided. In addition, the lower portion of the guider 12a may further include a cushioning rubber 54 to prevent the friction caused by the impact and frequent friction generated when contacting the magnet.

The fishing bobber thrown in the sea is erected on the surface of the water, and when the water is confirmed from the acquisition detection unit and the control unit operates the fishing bobber, the magnet 52 is located under the guider 12a. Then, when the fish catches the bait, the fishing bobber connected to the fishing line generates a momentary pulling force, which is temporarily locked in the surface of the fishing bobber. When the fishing bobbin 1 is suddenly moved by this pulling force, the magnet 52 which can be freely moved in the pulling direction is relatively moved to the top of the guider by inertia. The magnetic force sensor 51 located above the guider detects a change in magnetic force generated by the movement of the magnet, thereby detecting the presence of fish.

On the other hand, the control unit 60 is installed on the electric circuit board (E), and controls the operation relationship of the above-described intake detection unit 20, illuminance detection unit 30, the light emitting unit 40, the fishery detection unit 50. . In summary, the controller 60 starts the operation of the fishing bobber when it is determined that the fishing bobber 1 has been obtained from the acquisition detecting unit 20.

Thereafter, the illuminance measured by the illuminance sensing unit 30 is compared with a preset standard illuminance, and when the measured illuminance is greater than or equal to the standard illuminance, a charge such as a capacitor for high luminance light emission is prepared, and the measured illuminance is less than the standard illuminance. The main light emitting diode 42 emits low luminance.

Then, when the change in the magnetic force is measured by the fishery detector 50, the control unit 60 performs the high-luminance light emission as described above, or performs additional light emission.

In addition, the control unit 60 maintains light emission for a predetermined time when the fishing bobbin 1 is exposed and exposed to the air, and then shuts off the power so as to terminate the operation of the fishing bobber if there is no re-entry thereafter.

Thus, since the light emitting state is maintained for a predetermined time when the fishing bobber is collected at night, the user can easily measure the position of the sharp fishing hook, etc., thereby increasing safety during fishing.

On the other hand, the power for operation is supplied by a battery (B) located in the lower portion of the electrical circuit board. In this case, various types of ready-made products may be used as the battery.

However, it is preferable that the battery B having a large mass is disposed below the fishing bobber so that the fishing bobber 1 stands on the surface of the water.

Hereinafter, the specific configuration and operation of the illuminance-response fishing bobber according to the second embodiment of the present invention through the accompanying drawings.

Figure 2 is a partial cross-sectional view of the roughness response fishing bobber according to the second embodiment of the present invention. Roughness response type fishing bobber 1 'according to the second embodiment of the present invention has a rod shape.

The illuminance-response fishing bobber 1 'according to the second embodiment has a body portion 10', an intake detection portion 20, an illuminance detection portion 30, a light emitting portion 40, and a fishery detection portion 50 '. And a control unit 60.

On the other hand, the body portion 10 'is provided with a cap 11' of a transparent material formed on the upper portion, and a lower end cap 13 'detachably coupled to the cylindrical body 12' and the lower end.

An auxiliary electric circuit board E1 having an illuminance sensing unit and a light emitting unit is coupled to the inside of the cap 11 ', and connected to the auxiliary electric circuit board, and the main electric circuit board E2 including the control unit is connected to the body 12'. Erected and combined.

On the other hand, the fishery detecting portion 50 'has a cylindrical casing 51' attached to one side of the main electric circuit board E2 erected along the longitudinal direction of the body 12 'and a magnet freely moving along the casing longitudinal direction. 52 'and one side of the cylindrical case is provided with a magnetic force sensor 53' for measuring a change in magnetic force.

When the fish bobber 1 'is momentarily moved downward by the pulling force generated by the fishing of the bait, the magnet 52' inside the casing 51 'is relatively lifted by inertia. The magnetic force sensor 53 'recognizes the change in magnetic force caused by the magnetic force and determines that there is a fishery.

On the other hand, the configuration and operation of the acquisition detection unit 20, the illumination intensity detection unit 30, the light emitting unit 40 and the control unit 60 is the same as the illumination response type fishing bobber according to the first embodiment described above, Description is omitted.

Hereinafter, the specific configuration and operation of the illuminance-response fishing bobber according to the third embodiment of the present invention through the accompanying drawings.

3 is a cross-sectional view of the rough response responsive fishing bobber according to the third embodiment of the present invention, Figure 4 is a perspective view exploded main portion of the rough response responsive fishing bobber shown in FIG.

The illuminance-responsive fishing bobber 1 ″ according to the third embodiment includes a body portion 10, an intake detection portion 20 ″, an illuminance detection portion 30, a light emitting portion 40, and a fishery fish detection portion 50 ″. And a control unit 60.

The shape of the torso 10 is an egg like the first embodiment described above. In addition, the body portion 10 is divided into upper and lower body (11, 12), is assembled detachably by a screw thread in a state in which the waterproof ring 13 for sealing is interposed. In addition, the central cylinder (11a) is formed in the upper body 11, the lower body 12 is the same also provided with a guider (12a) surrounding the lower end of the central cylinder.

At this time, the fishery detection unit 50 ″ is provided on the upper portion of the electric circuit board E provided in the upper body tom 11, and the fishery detection unit 50 ″ is provided with a magnetic force sensor 51 on the upper portion. It is located at the upper portion of the hollow auxin case 55 and the auxiliary magnet 52a and the auxiliary magnet 52a fixed to the inner bottom of the case, and has the same polarity as the upper surface of the auxiliary magnet 52a on the lower surface of the repulsive force. The main magnet 52b spaced apart from the auxiliary magnet 52a and movable up and down is provided.

That is, the main magnet 52b which is movable up and down in the case 55 is moved upward from the inside of the case by inertia when the bobber is moved into the water by the pulling force. As a result, the magnetic force sensor 51 detects the movement of the main magnet to check the fishery.

At this time, as the auxiliary magnet (52a) is further provided, the main magnet (52a) is usually floating in the bottom surface of the fishery case, it is very sensitive to the pulling force can be raised immediately.

In other words, if the main magnet is in contact with the bottom surface of the credit case in advance, the main magnet should rise while the contact area is filled with air, but as the auxiliary magnet is further provided, an air layer is formed between the main magnet and the auxiliary magnet in advance. The main magnet is able to rise smoothly even by a small pulling force.

On the other hand, by adjusting the magnetic force of the auxiliary magnet (52a), or by adjusting the upper and lower length of the fishery case 55 may be different sensitivity of the fishery detection unit.

Thus, a number of illumination response fishing bobbers having different sensitivity may be prepared, and the illumination response fishing bobber having an optimal sensitivity may be selected and used according to the condition of the waves and the target fish.

On the other hand, the intake detection unit 20 ″ may be made of a capacitive proximity sensor that is fixed to the inner surface of the body portion (10).

At this time, the capacitive proximity sensor is provided inside the transparent or translucent body portion 10 when the fishing bobber is obtained and submerged in the water, the oscillation amplitude of the oscillation circuit when the high frequency oscillates in the oscillation circuit and is submerged in high quality water It consists of a commonly used capacitive proximity sensor that attenuates or stops and converts this change into an electrical signal to detect whether it is located in water.

Such a capacitive proximity sensor does not require a terminal submerged as in the above-described embodiments, and thus has the advantage that there is no reliability problem due to corrosion and contamination of the terminal.

In addition, it is also to have the advantage that can easily secure the space inside the lower body 12 for the placement of the battery to be described later.

On the other hand, the battery provided in the illumination response responsive fishing bobbin 1 ″ according to the third embodiment may be made using a ready-made coin-type battery (B1) is fitted into the empty space of the lower body (12).

That is, the coin type battery B1 is inserted into and fixed to the electric circuit board E provided between the guider 12a formed in the lower side of the body portion 10 and the body portion 10.

More specifically, the coin type battery has a central convex surface having a (-) polarity and an opposite surface having a (+) polarity, and is obliquely inserted into an inner bottom of the lower body 12 and fixed.

To this end, as shown in FIG. 3, one end B11 of the coin-type battery B1 is inserted between the bottom surface of the lower body 12 and the guider 12a, and the other end B12 is the lower body 12. The side portion of the state is leaning against the inner wall surface of the electric circuit board (E) is to be fixed.

At this time, the bottom surface of the circuit board (E) is formed with a metal surface (E10) for grounding to the (+) pole of the coin-type battery (B1), the center for grounding to the (-) pole of the coin-type battery The connecting leg E20 is coupled.

In this case, the user rotates the upper body 11 against the lower body 12 so that the connecting leg E20 is grounded to the (-) pole during the assembly of the fishing bobber, and when the upper body is completely assembled to the lower body, The metal surface E10 of the circuit board is connected to the positive electrode of the coin-type battery, so that power can be supplied to the electric circuit board.

In addition, when the use is finished, if the upper body 11 is rotated in the opposite direction and half separated from the lower body 12, the electric circuit board E rises and the positive electrode of the metal surface E10 and the coin-type battery and Power supply is cut off due to the disconnection of.

At this time, the lower body 12 may be further coupled to the weight (W) for adjusting the weight of the fishing bobber. In addition, the support jaw 12b may be further formed so that the coin-type battery can be securely fitted.

Meanwhile, as shown in FIG. 4, three coin-type batteries B1 may be inserted into the lower body 12 at equal intervals so as to center the center of gravity. The number of such coin-type batteries can be plural depending on the shape and size of the lower body.

In this case, the connection method of the coin-type battery is to change the circuit of the circuit board to meet the required voltage, and can be set in parallel or in series.

On the other hand, Figure 5 is a perspective view showing another battery of the illumination response responsive fishing bobber shown in FIG.

The battery B2 has a cylindrical shape in which a first electrode surface B21 is formed on an upper surface thereof, and a hollow cylindrical hole B20 is formed through the upper and lower portions so that the central cylinder 11a of the body portion passes through the center thereof. An inner circumferential surface of the ball B20 may have a second electrode surface B22 having a polarity opposite to that of the first electrode surface B21.

That is, by forming the battery (B2) as a single body, it is easy to install and replace the fishing bobber, adjust the material or thickness of the battery (B2) appearance and easily adjust the weight of the fishing bobber by varying the total weight of the battery You can do that.

Such batteries have a general configuration including a filling part in which an ammonium chloride solution, manganese dioxide, carbon powder, etc. are mixed, and a carbon rod submerged in the filling part, or a general mercury battery. It has a chemical reaction structure.

Since the cylindrical battery B2 has a shape that is filled in the lower body, the space of the filling part can be sufficiently secured, and thus a large capacity can be manufactured. Therefore, the fishing bobber can be used for a long period of time without frequent battery replacement, and it is possible to prevent connection failure due to frequent battery replacement.

At this time, in order to be connected to the first electrode surface B21 and the second electrode surface B22 of the battery B2, the bottom surface of the electric circuit board E has a metal surface E10 'corresponding to each electrode surface position. This can be formed. Even in this case, the first and second electrode surfaces B21 and B22 and the metal surface E10 'are grounded or separated according to the degree of rotation of the upper body, thereby acting as a power switch.

On the other hand, the cutting portion (B30) may be further formed to allow the fishing line to pass through the cylindrical hole (B20) in the side of the battery.

As the cutout portion B30 is formed, the user removes the upper body while fishing, passes the fishing line through the cutout portion B30 of the battery B2, and the replacement of the battery is not performed without removing the fishing line. It can be made easily.

Components other than the above description are the same as those of the first embodiment described above, and thus redundant descriptions are omitted.

On the other hand, while maintaining the main functions of the present invention, in addition to the first and second embodiments presented by the person skilled in the art can be reconfigured in the same or similar configuration to a jig having a variety of shapes other than holes and rods have.

According to the illuminance-response fishing bobber according to the embodiment of the present invention as described above, since the xenon lamp or light emitting diode is automatically selected to emit light so as to vary the intensity of the brightness according to the ambient illumination, the fishing bobber can be easily recognized. .

In particular, since the high brightness light emission of the xenon lamp is used during daytime speech is detected, the user can easily recognize that the speech is detected.

In addition, at night, it emits light as low as possible, i.e. at least low intensity enough to recognize the position of the fishing bobber, so as not to raise the alertness of the fish without need, and emits strong light that is visible to the user only when there is a certain fishery. , Fishing is made easier.

In addition, the fishing bobber is automatically operated by the control unit when the fishing bobber is obtained through the acquisition detecting unit, and the power is automatically cut off after a predetermined time after the collection, thereby simplifying the use of the fishing bobber.

In addition, since the light is emitted from the light emitting unit for a predetermined time after the recovery, the position of the sharp needle can be easily recognized, thereby preventing the safety accident during fishing.

In addition, the fishery detection unit using the inertia is simple in configuration and durable, and since the fish surely detects the moment when the fish catches the bait, it also has the effect of making fishing easier for beginners.

On the other hand, the auxiliary magnet is further provided has the effect that can be detected sensitively depending on the situation.

In addition, since the acquisition detecting unit is made of a capacitive proximity sensor, there is an effect that the problem of malfunction and shortening of life due to contamination of the terminal and the like are solved.

On the other hand, the ready-made product is easy to insert and replace when using a coin-type battery, it is also possible to easily center the center of gravity of the fishing bobber by placing a plurality of coil-type batteries at equal intervals. .

In addition, when the support jaw is further provided, the coin-type battery has an effect of being able to stably maintain and maintain a constant angle when fitting.

On the other hand, when using a cylindrical battery, it can be produced in a high capacity, so there is no need for frequent replacement, has an effect that can be used for a long time.

In addition, when the incision is further formed in the cylindrical battery, there is an effect that can easily replace the battery in the state without removing the fishing bobber from the fishing line.

Claims (12)

1. When the ambient light is high, high luminance is emitted when the fish is detected,

   When the ambient illuminance is low, low-luminance light emitting, when the fishery is detected, the illumination response responsive fishing bobber, characterized in that additional light is added as the light source is added, so as to increase the brightness than the low-luminance light emission.
2. In claim 1,

   The high luminance light emission when the ambient light is high is made of light of a xenon lamp or a large light emitting diode, the low luminance light emission when the ambient light is low is made of light of the main light emitting diode, and the light source for the additional light emission An additional illuminance-responsive fishing bobber, characterized in that the additional light emitting diode is made of light emission.
3. In claim 1,

   The fishery is a response response fishing bobber characterized in that it is determined by detecting a change in the magnetic force generated when the magnet is moved by inertia.
4. In claim 1, illuminance responsive fishing bobber

   Torso forming an appearance;

   An intake detection unit provided in the body to determine whether or not to obtain;

   An illumination sensing unit formed at an upper portion of the body to measure the ambient illumination;

   A light emitting unit provided with light emitting means for varying luminance for the high luminance light emission, the low luminance light emission, and the additional flashing;

   A fishery detection unit for sensing fishery with a pulling force generated when a fish catches a bait; And

   Power is supplied to the battery (B), and the operation is started by confirming the acquisition at the acquisition detection unit, and the high and low ambient illumination is determined by comparing the illumination measured by the illumination detection unit with a preset reference illumination. And a control unit configured to determine the operation of the light emitting unit and to perform the high luminance light emission or the additional light emission when the fishery is sensed by the fishery detection unit.
5. The method of claim 4, wherein the acquisition detection unit

   Illuminance responsive fishing bobber characterized in that it is determined whether or not obtained by the energization between the terminal ends spaced apart from the body portion.
6. In claim 4,

   The fishery detection department

   A magnetic force sensor is provided on the upper portion, the hollow case;

   An auxiliary magnet fixed to the inner bottom of the auxin case; And

   The upper part of the auxiliary magnet having the same polarity as the upper surface of the auxiliary magnet has a responsive responsive fishing bobber characterized in that the main magnet is spaced apart from the auxiliary magnet by the repulsive force and is movable up and down.
7. In claim 4,

   The acquisition detection unit

   Illuminance responsive fishing bobber comprising a capacitive proximity sensor fixed to the inner side of the body.
8. In claim 4,

   The battery

   Illumination-responsive fishing bobber characterized in that the coin-type battery is fixed to the guider formed in the lower side of the body portion and the electric circuit board (E) provided in the middle of the body portion.
9. In claim 8,

   The coin-type battery is an illumination response responsive fishing bobber characterized in that a plurality is provided with an isometric shape inside the egg-shaped body.
10. In claim 8,

    Illumination responsive fishing bobber characterized in that the support jaw for supporting the coin-type battery is further formed on the inner wall surface of the body portion.
11. In claim 4,

    The battery

    It is a cylindrical shape having a first electrode surface on the upper surface,

    A hollow cylindrical hole is formed in the center so as to penetrate up and down, and the inner circumferential surface of the cylindrical hole has a second electrode surface having a polarity opposite to that of the first electrode surface.
12. In claim 11,

    The battery

    Roughness responsive fishing bobber, characterized in that the incision further passes through the fishing line from the side to the cylindrical hole.

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