CN110915770B

CN110915770B - Method for realizing electronic control lure artificial bait

Info

Publication number: CN110915770B
Application number: CN201911315052.7A
Authority: CN
Inventors: 黄光佐
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-12-18
Filing date: 2019-12-18
Publication date: 2021-09-17
Anticipated expiration: 2039-12-18
Also published as: CN110915770A

Abstract

The invention relates to the field of lure simulation baits, discloses an implementation method of an electronic control lure simulation bait, relates to an implementation method of how the lure simulation bait simulates sound and vibration waves generated when a lure fish swims and reflects external light rays when the lure simulation bait swims after entering water, and solves the problem that the lure fish can only simulate the swimming of the lure fish by an operation method of a fishing hand in the prior lure simulation bait. The electronic control lure transmits sound and vibration waves to a far place by controlling the vibration of the miniature vibration motor; and the LED lamps are controlled to periodically emit light intermittently to simulate the reflection effect of the light on the outside when the artificial bait fish swims, so that the effect of inducing the lure object fish to attack the lure object fish is achieved. The electronic control lure is mainly composed of main modules and components such as a control circuit, a micro vibration motor, an LED lamp, a water inlet inspection circuit and the like.

Description

Method for realizing electronic control lure artificial bait

Technical Field

The invention relates to the field of lure simulation, in particular to a method for realizing electronic control lure simulation, which is used for effectively simulating vibration waves and sound generated when lure fishes swim and reflection of ambient light when the lure fishes swim when the lure fishes are used for fishing in the lure, so that lure object fishes can actively attack the electronic control lure simulation, the lure motion is simpler, and the probability of fish in the lure is increased.

Background

Along with the improvement of living standard of people and the diversification of leisure modes, more and more people select the way to fish as the mode of leisure exercise. When the lure artificial bait is used for fishing, the lure artificial bait selected by a fishing hand can only be common bait, and the sound generated when the lure artificial fish swims and the characteristic of reflecting ambient light can not be actively moved, so that the probability of the fishing hand in fishing is greatly reduced.

When the lure fish is caught, the lure fish is mainly caught by the vibration wave and the sound wave generated when the lure fish moves in water, which are sensed by the lateral line of the fish (the sensing frequency is between 10HZ and 100HZ, so that the fundamental wave or the harmonic wave of the vibration frequency of the vibration motor can be controlled between 10HZ and 100 HZ), and then the lure fish is also caught by sensing the reflected light of the lure fish to the ambient light when the lure fish moves in water to determine the position of the lure fish.

Disclosure of Invention

Based on the problems, the invention provides the method for the electronically controlled lure after the lure fish actively simulates the lure fish to generate vibration waves and sound waves and simulates reflected ambient light after entering water, so as to induce the lure object fish to actively attack the lure, and the lure becomes simple and interesting; meanwhile, the probability of fish catching is greatly improved. The invention aims to enable lure artificial bait to actively control the shake wave and the sound wave generated when lure artificial fish swim and the electronic control lure artificial bait reflected to the ambient light when swim after the lure artificial bait enters water, so that the performance of the lure artificial bait in water is closer to the bait fish characteristic of the lure artificial fish.

In order to achieve the purpose, the following technical scheme is adopted:

an implementation method of an electronic control lure comprises the lure, wherein an inner cavity of the lure comprises a water inlet detection system, an LED light-emitting system, a micro vibration motor system and a control circuit board.

In the water-entering detection system, because water has certain conductive property, when detecting whether the water-entering electrode and the ground electrode of the control circuit are contacted with water, a certain resistance R3 is presented between the two electrodes, and when the two electrodes are not contacted with water, the resistance value of R3 between the two electrodes is infinite, by utilizing the characteristic, the resistance R1 is indirectly fixed between the circuit working voltage and the detection electrode, the resistance R2 is indirectly fixed between the detection electrode and the circuit working ground, and the voltage formula for detecting whether the water-entering electrode is contacted with water when the water is not entered is as

When entering water, the voltage formula for detecting whether the electrode enters the water is as follows

Detecting whether the sub-lure is immersed in water or not according to the voltage change of the electrodes when the electrodes are not immersed in water and are immersed in water, so as to close and open related circuits, wherein the detection result shows whether the electrodes immersed in water are in point connection with the ground electrode of the control circuit and the control circuit board; the voltage change of the water-entering detection point can be detected by a voltage comparator, an A/D conversion method, a voltage frequency conversion method and the like.

In the LED light-emitting system, an LED lamp 107 is included, the LED lamp 107 is electrically connected with a control circuit board 103, two sides of the lure 102 are respectively provided with a closed light-transmitting window with proper size, so that LED light can be transmitted in water through the side wall light-transmitting window of the lure 102; when the lure 102 is not put into water, the LED lamp 107 is turned off; when the lure fish 102 enters water, the control circuit turns on the LED lamp 107 at a certain period to make the LED lamp 107 flash, so that the reflecting effect of the lure fish on external light rays when swimming in water can be simulated.

The micro vibration motor 109 system comprises a micro vibration motor 109, and the micro vibration motor 109 is electrically connected with the control circuit board 103, so that when the micro vibration motor 109 is started, the side edges of the micro vibration motor 109 can freely strike two inner side edges of the fish-shaped lure 102 during vibration, and the effects of vibration waves and sound emission from the side edges are achieved; when the lure 102 is not in water, the micro-vibration motor 109 is turned off; after the lure 102 enters water, the control circuit starts the micro-vibration motor 109 at a certain period to vibrate the micro-vibration motor 109, and the micro-vibration motor 109 can knock two inner side edges of the fish-shaped lure 102 when vibrating, so that the knocking sound can be transmitted to the water; meanwhile, the vibration wave of the micro vibration motor 109 can be transmitted in the water through the fish-type lure 102, so that the sound wave and the vibration wave generated by the lure fish swimming in the water can be simulated.

Due to the adoption of the technical scheme, the invention has the effects that:

1. when the lure is not put into water; the whole control system is in a dormant state, and the LED and the micro vibration motor are turned off, so that the aim of saving electricity of the system is fulfilled;

2. when the lure artificial bait enters water, the LED and the miniature vibration motor are periodically started, so that the lure artificial bait can fully simulate the sound wave of the lure fish when swimming and reflect the characteristics of external light, and can swim in water more like the lure fish after the lure artificial bait enters water, so that the lure object fish actively attacks the lure artificial bait.

Drawings

FIG. 1 is a schematic view of the present invention;

FIG. 2 is a schematic diagram of the distribution of the water-entering detection system, the LED light-emitting system and the micro-vibration motor system in the lure;

FIG. 3 is a circuit diagram of the water electrode in FIG. 1 and FIG. 2;

FIG. 4 is a schematic diagram of a micro-vibration motor system:

the device comprises a 101-path sub-line connecting metal ring, a 102-path sub-lure, a 103 control circuit board, a 104 lithium battery charging anode, a 105 control circuit ground electrode, a 106 detection water inlet electrode, a 107LED lamp, a 108LED light-transmitting window, a 109 micro vibration motor, a 110 lithium battery, a 111-path sub-hook connecting metal ring, a 112-path sub-lure metal counterweight block and a 201 vibration motor electrode lead.

Detailed Description

The following are embodiments of the invention:

example 1:

an electronic control lure realization method comprises a lure 102, wherein the lure 102 comprises a water detection system, an LED light-emitting system and a micro vibration motor system.

In the water-entering detection system, because water has certain conductive characteristics, when whether the water-entering electrode 106 and the control circuit ground electrode 105 are in contact with water is detected, a certain resistance R3 is presented between the two electrodes, and when the two electrodes are not in contact with water, the resistance value of R3 between the two electrodes is infinite, by using the characteristics, the resistance R1 is indirectly fixed between the circuit working voltage and the detection electrode, the resistance R2 is indirectly fixed between the detection electrode and the circuit working, and the voltage formula for detecting whether the water-entering electrode 106 is detected when water is not entered is as follows:

the voltage formula for detecting whether the electrode 106 enters water when entering water is as follows:

detecting whether the sub-lure 102 enters water or not according to the voltage change of the electrodes when the electrodes do not enter water and enter water, realizing the closing and opening of related circuits, and detecting whether the water entering electrode 106 is in point connection with the control circuit ground electrode 105 and the control circuit board; the voltage change of the water-entering detection point can be detected by a voltage comparator, an A/D conversion method, a voltage frequency conversion method and the like.

Referring to fig. 1 and fig. 3 to 4 in this embodiment, R1 is a fixed resistor connected to the positive VCC terminal of the lithium battery 110 and the terminal for detecting whether to enter the water electrode 106, R2 is a fixed resistor connected to the terminal for detecting whether to enter the water electrode 106 and the negative GND terminal of the lithium battery 110, and R3 is equivalent to an equivalent resistor connected to the terminal for detecting whether to enter the water electrode 106 and the negative GND terminal of the lithium battery 110. When the lure 102 is not immersed in water, the voltage at the water detection point is as follows, since R2 is much larger than R1

Close to the VCC voltage; when the lure 102 is immersed in water, the resistance value of R3 is equivalent to a constant value in the circuit due to the conductivity of water, and the voltage at the point of detection of immersion is equal to the voltage at the point of detection of immersion due to the partial pressure of R3

. The proper values of R1 and R2 are selected, the voltage of the water-entering detection point can obviously change when water enters or does not enter, and the voltage change of the point is detected by the control circuit, so that whether the lure 102 enters water can be detected. The voltage change of the water-entering detection point can be detected by a voltage comparator, an A/D conversion method, a voltage frequency change method and the like.

Through the water inlet detection system, the whole control system can work in a power-saving state, namely when the lure 102 does not enter water, the whole control system works in a dormant state, so that the power consumption of the control system is the lowest; when the lure 102 is immersed in water, the entire control system operates in a normal state. The LED lamp 107 is arranged on the control circuit board 103, and the closed light-transmitting windows are respectively arranged on two side edges of the lure 102, so that LED light can be transmitted in water. When the lure 102 is not in water, the LED lamp 107 is turned off, and the micro vibration motor 109 is turned off; when the lure 102 enters water, the control circuit turns on the LED lamps 107 at a certain period to enable the LED lamps 107 to flicker, so that reflection of the lure fish to external light rays when swimming in water can be simulated, and the control circuit turns on the micro vibration motor 109 at a certain period when entering water to enable the micro vibration motor 109 to vibrate, so that after the lure fish enters water, the micro vibration motor 109 can knock two inner side edges of the lure 102 when vibrating, and knocking sound can be transmitted to the water; meanwhile, the vibration wave of the micro vibration motor 109 can be transmitted in the water through the fish-shaped lure 102, so that the characteristic of the lure fish swimming in the water can be simulated.

Specifically, VCC in fig. 3 is the operating voltage of the control circuit, that is, the voltage of the positive electrode of the lithium battery 110; GND is the working ground of the control circuit; r1 is a fixed resistance between VCC and the detecting water entry electrode 106; r2 is a fixed resistor between the water inlet electrode 106 and the control circuit working ground GND, wherein R2 is far larger than R1; r3 is the equivalent resistance between the electrode 106 and the control circuit working ground GND for detecting whether water enters or not, and is infinite when water does not enter, and is far less than R1 and R2 after water enters.

Specifically, the charging positive electrode of the lithium battery 104 is connected to the control circuit 103.

Specifically, the 107LED lamp is connected to the control circuit 103.

Specifically, the resistance of R1 is 1 megohm to 100 megohm.

Specifically, the resistance of R2 is more than 10 times that of R1, and an open circuit can be realized in an actual circuit.

Specifically, R3 is equivalent to a certain resistance value in the circuit, which may range from 1K ohm to 100K ohm depending on the water body.

Specifically, in the control circuit, the 107LED lamp is turned on at a frequency of 0.5Hz to 100Hz and at a duty ratio of 1% to 50%.

Specifically, in the control circuit, the starting period of the lamp of the 109 miniature vibration motor is 0.5HZ to 100HZ, and the duty ratio is 1 percent to 50 percent.

Example 2:

on the basis of the above embodiment, the present embodiment shows that the micro-vibration motor system is arranged at the lower part of the front end of the inner cavity of the lure 102; the lithium battery 110 is arranged in the middle of the upper inner cavity of the lure 102. The effect of this installation is that the space in the rear part of the upper inner cavity of the lure 102 can be fully utilized to install the battery with larger capacity, increasing the working time of the system.

Referring to fig. 2 and fig. 3 to 4 in this embodiment, R1 is a fixed resistor connected to the positive VCC terminal of the lithium battery 110 and the terminal for detecting whether to enter the water electrode 106, and R2 is a fixed resistor connected to the terminal for detecting whether to enter the water electrode 106 and the negative GND terminal of the lithium battery 110; r3 is equivalent to the equivalent resistance connected between the end for detecting whether the water inlet electrode 106 is connected to the negative GND terminal of the lithium battery 110. When the lure 102 is not submerged, the voltage at the point of detection of water entry is as follows, since R2 is much larger than R1

. The proper values of R1 and R2 are selected, the voltage of the water-entering detection point can obviously change when water enters or does not enter, and the voltage change of the point is detected by the control circuit, so that whether the lure 102 enters water can be detected. The voltage change of the water-entering detection point can be detected by a voltage comparator, an A/D conversion method, a voltage frequency change method and the like. Through the water inlet detection system, the whole control system can work in a power-saving state, namely when the lure 102 does not enter water, the whole control system works in a dormant state, so that the power consumption of the control system is the lowest; when the lure 102 is immersed in water, the entire control system operates in a normal state. The LED lamp 107 is arranged on the control circuit board 103, and the closed light-transmitting windows are respectively arranged on two side edges of the lure 102, so that LED light can be transmitted in water. When the lure 102 is not in water, the LED lamp 107 is turned off, and the micro vibration motor 109 is turned off; when the lure 102 enters water, the control circuit turns on the LED lamp 107 at a certain period to enable the LED lamp 107 to flicker, so that reflection of the lure fish to external light rays when swimming in water can be simulated, the control circuit turns on the micro vibration motor 109 at a certain period when entering water to enable the micro vibration motor 109 to vibrate, and the micro vibration motor 109 can knock two inner sides of the lure 102 so as to enable knocking sound to be transmitted in water; meanwhile, the vibration wave of the micro vibration motor 109 can be transmitted in the water through the fish-shaped lure 102, so that the characteristic of the lure fish swimming in the water can be simulated.

Specifically, the micro-vibration motor 109 is arranged at the lower part of the front end of the lure 102, and when the micro-vibration motor 109 is turned on, the sides of the micro-vibration motor 109 can freely strike two inner sides of the fish-type lure 102.

The above embodiments only express the specific embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for those skilled in the art, without departing from the technical idea of the present application, several changes and modifications can be made, which are all within the protection scope of the present application.

Claims

1. An implementation method of an electronic control lure, comprising a lure (102), characterized in that: the inner cavity of the lure (102) comprises a water inlet detection system, an LED light-emitting system, a micro vibration motor system and a control circuit board (103);

in the water inlet detection system, because water has certain conductive property, when whether a water inlet electrode (106) and a control circuit ground electrode (105) are contacted with water is detected, certain resistance R3 is presented between two electrodes, and when the two electrodes are not contacted with water, the resistance value of R3 between the two electrodes is infinite, by utilizing the characteristic, a fixed resistor R1 is connected between a circuit working voltage and the detection of whether the water inlet electrode is connected, the resistor R2 is indirectly fixed when the detection of whether the water inlet electrode is connected with the circuit working, and the voltage formula for detecting whether the water inlet electrode (106) is connected when the water is not introduced is the same as that of the circuit working voltage and the detection of whether the water inlet electrode is connected with the circuit working, wherein the voltage formula for detecting whether the water inlet electrode (106) is connected or not is the water inlet electrode

When entering water, the voltage formula for detecting whether the electrode (106) enters the water is as follows

The VCC is the positive voltage of the lithium battery (110); detecting whether the sub-lure (102) enters water or not according to the voltage change of the electrodes when the electrodes do not enter water and enter water, so as to realize closing and opening of related circuits, wherein the electrodes (106) for detecting whether the electrodes enter water and the ground electrode (105) of the control circuit are in point connection with the control circuit board; the voltage change at the water-entering detection point can be detected by a voltage comparator, an A/D conversion method or a voltage frequency conversion method.

2. The method for realizing the electronically controlled lure according to claim 1, wherein: the LED light-emitting system comprises an LED lamp (107), the LED lamp (107) is electrically connected with a control circuit board (103), two closed light-transmitting windows with proper sizes are respectively arranged on two side edges of the lure (102), and LED light is enabled to transmit in water through the light-transmitting windows on the side walls of the lure (102); when the lure (102) does not enter water, the LED lamp (107) is turned off; when the lure fish (102) enters water, the control circuit turns on the LED lamp (107) at a certain period to enable the LED lamp (107) to flicker, and therefore the reflecting effect of the lure fish on external light rays when swimming in water can be simulated.

3. The method for realizing the electronically controlled lure according to claim 1, wherein: the miniature vibration motor (109) system comprises a miniature vibration motor (109), and the miniature vibration motor (109) is electrically connected with the control circuit board (103), so that when the miniature vibration motor (109) is started, the side edges of the miniature vibration motor (109) can freely knock two inner side edges of the fish-shaped lure (102) during vibration to achieve the effects of vibration waves and sound emission by knocking the side edges; when the lure (102) is not in water, the micro-vibration motor (109) is closed; after the lure (102) enters water, the control circuit starts the micro vibration motor (109) in a certain period to vibrate the micro vibration motor (109), and the micro vibration motor (109) can knock two inner side edges of the fish-shaped lure (102) during vibration, so that knocking sound can be transmitted to the water; meanwhile, the vibration wave of the miniature vibration motor (109) can be transmitted in water through the fish-shaped lure (102), so that the sound wave and the vibration wave generated by the lure fish swimming in the water can be simulated.