阅读说明：本技术 一种带导流槽硬尾重力感应变光电子浮漂及变光控制方法 (Hard tail gravity sensing strain photoelectron buoy with diversion trench and light-changing control method ) 是由 彭海平 于 2020-07-01 设计创作，主要内容包括：本发明涉及一种带导流槽硬尾重力感应变光电子浮漂,包括漂身、漂尾和漂脚,所述的漂身内部设置电源和控制电路,所述的漂尾为硬尾设置有若干可变光的小灯泡,每个小灯泡上设置一个枣核形的醒目豆,醒目豆的中心设置有贯穿的套孔,套设在漂尾上的小灯泡处,或者醒目豆与漂尾为一体结构,醒目豆外周设置至少二个上下方向的导流槽,所述的漂尾的中心或表面开槽,连接小灯泡的导线通过开槽与漂身内的控制电路连接；所述的控制电路包括重力传感器或加速度传感器,以及MCU,所述的MCU接收重力传感器或加速度传感器的数据并控制小灯泡变光,MCU上电一次切换一次变光的灵敏度,灵敏度至少具有二挡循环。本发明入水阻力小、醒目、变光灵敏度可调,适应性强。(The invention relates to a hard tail gravity sensing strain photoelectron buoy with a diversion trench, which comprises a buoy body, a buoy tail and buoy feet, wherein a power supply and a control circuit are arranged in the buoy body, the buoy tail is a hard tail provided with a plurality of light-variable small bulbs, each small bulb is provided with a jujube-core-shaped striking bean, the center of each striking bean is provided with a through sleeve hole which is sleeved at the small bulb on the buoy tail, or the striking bean and the buoy tail are integrated into a whole, the periphery of each striking bean is provided with at least two diversion trenches in the vertical direction, the center or the surface of the buoy tail is grooved, and a lead wire connected with the small bulb is connected with the control circuit in the buoy body through the grooves; the control circuit comprises a gravity sensor or an acceleration sensor and an MCU, the MCU receives data of the gravity sensor or the acceleration sensor and controls the small bulb to change light, the MCU is electrified to switch the sensitivity of the light change once, and the sensitivity has at least two cycles. The invention has small and striking resistance to water entry, adjustable light-changing sensitivity and strong adaptability.)

1. The utility model provides a take hard tail gravity of guiding gutter to feel optoelectronic float that meets an emergency which characterized in that: the multifunctional float comprises a float body, a float tail and float feet, wherein a power supply and a control circuit are arranged in the float body, the float tail is a hard tail, a plurality of serially or parallelly connected variable light small bulbs are arranged on the float tail, each small bulb is provided with a jujube-core-shaped or oval striking bean, the striking beans are small in size, large in size and small in size and are symmetrical up and down, a through sleeve hole is formed in the center of each striking bean, the striking beans are sleeved at the small bulbs on the float tail or are integrated with the float tail, at least two guide grooves in the up-and-down direction are uniformly formed in the periphery of each striking bean, the center or the surface of the float tail is provided with a groove, and a lead wire connected with the small bulbs is connected with the control circuit in the float body through the grooves; the control circuit comprises a gravity sensor or an acceleration sensor and an MCU, the MCU receives data of the gravity sensor or the acceleration sensor and controls the small bulb to change light, the MCU is electrified to switch the sensitivity of the light change once, and the sensitivity of the light change has at least two cycles.

2. The hard tail gravity strain sensing optoelectronic float with a flow guide groove according to claim 1, is characterized in that: each flow guide groove comprises two planes or cambered surfaces, and the two planes or cambered surfaces form an included angle of 20-170 degrees.

3. The hard tail gravity strain sensing optoelectronic float with a flow guide groove according to claim 2, is characterized in that: the included angle points to the center of the jujube-pit-shaped striking bean, and the corner is provided with a chamfered edge or a chamfered corner.

4. The hard tail gravity strain sensing optoelectronic float with a flow guide groove according to claim 1, is characterized in that: the flow guide groove is internally provided with a coating with a color different from that of the striking beans, and the coating is of a single color or at least two colors which are distributed at intervals.

5. The channeled hard tail gravity strain sensitive optoelectronic float of claim 1, further comprising the following functions: judging the direction of the buoy when the buoy is powered on, and only lighting when the buoy tail is downward; otherwise, the light may be changed.

6. A photoelectron floating light-changing control method for hard tail gravity sensing strain with a diversion trench is characterized in that an MCU executes the following steps:

powering up;

reading a dimming sensitivity control command, and switching a primary dimming sensitivity control command;

controlling the times corresponding to the control command of the small bulb flicker and the light changing sensitivity;

waiting for data from the gravity sensor or the acceleration sensor.

7. A dimming control method as claimed in claim 6, wherein: the MCU reads the data of the gravity sensor or the acceleration sensor before reading the dimming sensitivity control command, judges the direction of the electronic float, and controls the small bulb to emit light if the tail of the electronic float is downward; otherwise, executing the reading dimming sensitivity control command and the subsequent steps.

8. A dimming control method as claimed in claim 6, wherein: the corresponding relation between the twinkling times of the small bulb and the light-changing sensitivity control command is as follows: the higher the dimming sensitivity, the more the small bulb flickers, or the less the small bulb flickers.

Technical Field

The invention relates to the technical field of floats, in particular to a striking structure of a float tail.

Background

The float is one of the indispensable equipment of fishing activity for stabilize the fishhook position and indicate whether have the fish to get on the hook, and the instruction function wherein is accomplished mainly by floating the tail. In order to improve the visibility of the buoy, the striking beans with various colors and sizes appear in the market, and the striking beans are sleeved on the floating tail to increase the visible area of the floating tail or make the color of the floating tail more vivid and visible.

Meanwhile, in order to adapt to night fishing, the luminous electronic float with the luminous function also forms a larger market.

However, whether the conventional float or the electronic float is adopted, the currently common striking beans are usually smooth cylinders, fusiform shapes and the like, have heavy floating tails, are single in form and not striking, and have large water entry resistance.

In addition, the existing part of electronic floats have a light changing function, namely, the floats emit light of one color when floating, and if a fish catches on the hook to drag the floats, the floats can change into light of another color to prompt a fisherman. The sensitivity of the light-changing buoy is fixed, and due to the fact that the force ways of big fishes and small fishes are different and disturbance of environment wind blowing, the light-changing function can generate a lot of false actions, and the using effect is poor.

Disclosure of Invention

The invention aims to improve and innovate the defects and problems in the background art and provides an electronic float with small water inlet resistance, striking and adjustable light-changing sensitivity.

The invention has the technical scheme that a gravity-sensitive strain photoelectron buoy with a guide groove and a hard tail comprises a buoy body, a buoy tail and buoy feet, wherein a power supply and a control circuit are arranged in the buoy body, the buoy tail is a hard tail, a plurality of serially or parallelly connected light-variable small bulbs are arranged on the buoy tail, each small bulb is provided with a jujube-kernel-shaped or oval striking bean, the striking beans are small in upper part, large in middle part and small in lower part and are symmetrical in upper and lower parts, the centers of the striking beans are provided with penetrating trepanning holes which are sleeved at the small bulbs on the buoy tail or are integrated with the buoy tail, at least two guide grooves in the upper and lower directions are uniformly arranged on the periphery of the striking beans, the center or the surface of the buoy tail is provided with a groove, and a lead wire connected with the small bulbs is connected with the control circuit in the buoy body through the groove; the control circuit comprises a gravity sensor or an acceleration sensor and an MCU, the MCU receives data of the gravity sensor or the acceleration sensor and controls the small bulb to change light, the MCU is electrified to switch the sensitivity of the light change once, and the sensitivity of the light change has at least two cycles.

Furthermore, each flow guide groove comprises two planes or cambered surfaces, and the two planes or cambered surfaces have an included angle of 20-170 degrees.

The included angle points to the center of the jujube-pit-shaped striking bean, and the corner is provided with a chamfered edge or a chamfered corner.

The flow guide groove is internally provided with a coating with a color different from that of the striking beans, and the coating is of a single color or at least two colors which are distributed at intervals.

The small bulb is an LED or other luminous bodies.

Another technical scheme of the invention is to construct an electronic float color changing method, wherein an MCU executes the following steps:

powering up;

reading a dimming sensitivity control command, and switching a primary dimming sensitivity control command;

controlling the times corresponding to the control command of the small bulb flicker and the light changing sensitivity;

waiting for data from the gravity sensor or the acceleration sensor.

Preferably, the MCU reads the data of the gravity sensor or the acceleration sensor before reading the dimming sensitivity control command, judges the direction of the electronic float, and controls the small bulb to emit light if the tail of the electronic float is downward; otherwise, executing the reading dimming sensitivity control command and the subsequent steps.

The corresponding relation between the twinkling times of the small bulb and the light-changing sensitivity control command is as follows: the higher the dimming sensitivity, the more the small bulb flickers, or the less the small bulb flickers.

The invention has the advantages and beneficial effects that: according to the invention, the jujube-pit-shaped or oval striking beans are added with the thick floating tails, and the guide grooves are arranged on the striking beans, so that the integral water inlet resistance of the buoy can be reduced, and the weight of the floating tails is reduced. The coating that the colour is different from striking beans main part is set up in the guiding gutter for striking beans colour is more, more obvious, observes when being favorable to fishing. Gravity sensor or acceleration sensor can respond to the motion of floating body, makes the small bulb discolour when judging that there is the fish to get on the hook, reinforcing suggestion effect. And at least two levels of sensitivity are adjusted, so that switching can be performed according to different application scenes, and misoperation is reduced. The electronic buoy can be used as a conventional normally-bright buoy by inserting the battery upside down.

Drawings

Fig. 1 is a schematic view of the overall structure of the embodiment.

Fig. 2 is a view a-a of fig. 1.

Fig. 3 is a schematic diagram of a light emitting circuit.

FIG. 4 is a view B-B of FIG. 1 in one embodiment.

Fig. 5 is a view B-B of fig. 1 in another embodiment.

Fig. 6 and 7 are schematic diagrams of another two structures of the diversion trench.

FIG. 8 is a flowchart of example 3.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "disposed" on another element, it can be directly disposed or attached to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.