CN212813702U - Day and night dual-purpose electronic buoy - Google Patents

Abstract

The utility model discloses a day night double-purpose electron is cursory, the electron is cursory including built-in LED light emitting component float tail subassembly, float body subassembly and can conveniently pack into and float the luminous battery of tail subassembly switch-on LED light emitting component. The floating tail assembly consists of an outer tube, an optical fiber rod, an LED light-emitting group, a floating tail seat, a protective sleeve and a sealing ring sleeved on the floating tail seat; the outer surface of the outer tube is coated with an outer tube for floating, a plurality of shading areas are attached to the surface of the optical fiber, and optical fiber luminous floating meshes are arranged on two sides of each shading area; the outer pipe is a parallel straight pipe with the unchanged inner diameter and outer diameter, or the outer pipe is a taper outer pipe with the gradually increased outer diameter, or the outer pipe is a striking taper pipe with a striking area at the tip of the taper pipe. The utility model provides an electron is cursory can better compromise the fishing demand daytime and evening.

Description

Day and night dual-purpose electronic buoy

Technical Field

The utility model relates to a fishing tackle field especially relates to an electron of day night double-purpose is cursory.

Background

The float, one of important fishing tools for fishing, is used for transmitting information that fishes swallow baits, and corresponds to a day float for day and an electronic float for night, also called a luminous float, and is different from the day float and the electronic float. Fig. 1 shows a typical daily bleaching solution, which mainly comprises a bleaching tail 90, a bleaching body 91 and bleaching feet 92, wherein the bleaching tail 90 is formed by grinding viscose glue, a color area 902 and a color area 903 are formed on the outer surface of the bleaching tail 90 in sequence from the tip of the bleaching tail to the root of the bleaching tail through painting, the color area 902 and the color area 903 are alternately arranged, a color separation area 901 is coated at the junction, the color area 902 and the color area 903 are colored and have different colors, the color separation area 901 is dark color, usually black, and the color areas 901, 902 and 903 jointly form the bleaching mesh of the bleaching tail. The floating tail 90 is made of glass fiber, carbon fiber, plastic-drawing forming tube and the like. The daily bleaching is typically characterized in that the width of the color separation area 901 is narrow, usually about 3 mm, and the bleaching tail 90 has enough rigidity and good elasticity and is not easy to damage.

For the night electronic float, fig. 2 shows a typical electronic float solution, which mainly comprises an optical fiber 83, a transparent protection tube 80 sleeved outside the optical fiber, a float body 81 and a float foot 82. The inside of the float body 81 is also provided with a corresponding LED light-emitting element and a corresponding battery, and the float foot 82 and the float body 81 are fixed together through bonding and polishing treatment. The optical fiber 83 is a light guide part, the common material is PMMA plastic, compared with the material of a daily float tail, the PMMA material is easy to damage, and the rigidity is poor, so that the transparent protection tube 80 is additionally arranged on the outer side of the optical fiber 83 to play roles of protecting the optical fiber, improving the rigidity and the like. The optical fiber 83 is repeatedly coated with a color zone 832, a color separation zone 831 and a color zone 833 from the floating tail tip to the floating tail root in sequence, thereby forming a floating eye. The color zones 832 and 833 are surface-painted light-transmissive areas to allow light to shine out. The electronic float is typically characterized in that the color separation zone 801 has a wider width, usually about 10 mm, than the color separation zone 901 of the daily float, and is used for protecting the optical fiber 83, and a protection tube 80 is usually sleeved outside the color separation zone, and the protection tube 80 is made of a transparent material. As shown in fig. 3, the purpose of widening the electronic bleaching separation region 831 is to enable human eyes to distinguish the color region 832 and the color region 833 under a night environment, so as to avoid the effect that the effect is connected after the tail is observed by the eyes to be shiny, and the effect of clear resolution without daily bleaching is achieved. As known to those skilled in the art, the floating eyes of the float are used as signal prompts for judging that the fish eats the hook, and the condition that the fish eats the hook is analyzed by judging the change of the floating eye quantity on the exposed water surface.

The prior art has also provided the electronic float of day night double-purpose, but the solution of current day night double-purpose float all has the shortcoming, as a day night double-purpose float shown in figure 4, compare the typical electronic float shown in figure 2, for taking into account that the day corresponds color separation district 731 and no longer widens, but follow the width of day float, this kind of scheme can reach daily effect, but use at night as shown in figure 5, will be bright back and become one piece, can't distinguish and float the mesh, consequently as the solution shown in figure 6 again, interval one floats mesh luminous, however the interval width W7(2) between two luminous float meshes is too wide again, greatly reduced float mesh judgement sensitivity, to the fish condition of light stuttering hook, the signal prompt timeliness of float reduces. In another prior art, CN209628432U discloses a solution, wherein a first color-coated transparent protection tube and a second color-coated transparent protection tube are sequentially and alternately sleeved and fixed on the outer side of an optical fiber rod coated with color and color separation regions by glue, which is a complex manufacturing process, and a plurality of protection tubes are required to be nested and glued, and on the other hand, the first color-coated protection tube covers the black part of the optical fiber, and the second color-coated protection tube covers the color part of the optical fiber, which means that when the optical fiber is used as a daily float, the observable float eyes are the first color-coated region and the second color-coated region, and no color separation region is available for the daily float, so that the operation habit of the daily float of a fishing person is changed to a certain extent, and the outer surface of the float tail sleeved with the large and small color-coated transparent protection tubes is represented by the large, small, large and small outer surfaces which are circularly and alternately, i.e. a plurality of high and low steps, and water cutting efficiency, and meanwhile, the sensitivity is reduced, in addition, if the color-coated protection tube is used as a daily float, the length of the first color-coated protection tube and the second color-coated protection tube needs to reach the size similar to that of a common float, the color-coated protection tube is used at night and is light-tight to form a color separation area for night floating, the width size of the color separation area is much larger than that of the common daily float, the sensitivity of the float is reduced, and otherwise, if the width at night is ensured, the daily process float is too short.

In view of above, the technical scheme that current day night double-purpose was floated all not realize that daily state is the same with current traditional day is used, and uses at night and can reach the visual effect of night and simultaneously not obviously reduce the effect of floating mesh sensitivity.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve the prior art shortcoming that the background art mentioned, provided a day night double-purpose electron cursory.

In order to achieve the above object, the utility model provides a following technical scheme: a day and night dual-purpose electronic buoy comprises a buoy tail assembly, a battery and a buoy body assembly, wherein the buoy tail assembly is sequentially detachably connected with the battery and the buoy body assembly and comprises an outer tube, an optical fiber, a protective sleeve, an LED light-emitting element and a sealing ring, the outer tube is in a hollow tubular shape, and the optical fiber is inserted into an inner hole of the outer tube to form an inner-outer assembly relation;

the outer surface of the outer tube is coated with a plurality of color areas which have different colors and are alternately arranged to form an outer tube floating mesh;

a plurality of spaced light shielding areas are attached to the outer surface of the optical fiber, and the light shielding areas can block or reduce the light of the LED from irradiating outwards in the light shielding areas;

the outer pipe is a parallel straight pipe with the unchanged inner diameter and outer diameter, or the outer pipe is a taper outer pipe with the gradually increased outer diameter, or the outer pipe is a striking taper pipe with a striking area at the tip of the taper pipe.

Specifically, a color separation area is arranged between two adjacent color areas on the outer screen, the color of the color separation area is a dark color system and plays a role in color separation, the axial width of the color separation area is W (1), and the size of the W (1) is 2-4 mm; the width dimension W (2) of the optical fiber shading area has the dimension relation that W (2) is more than or equal to W (1); and viewed in radial projection, the axial directions of the color separation area width W (1) of the outer tube and the shading area width W (2) have a complete overlapping or partial overlapping or end-to-end splicing position relationship.

Specifically, a light transmitting area is formed on the outer surface outside the optical fiber shading area through secondary processing, and the LED light emits light through the light transmitting area.

Specifically, the outer surface outside the optical fiber shading area is coated with a color area to form an optical fiber floating eye.

Specifically, the outer pipe is made of a single material which is integrally formed.

Specifically, the outer tube is formed by splicing a plurality of tubes and is fixed on the outer side of the optical fiber through glue, and the position of the splicing part is located in the width range of the optical fiber shading area along the axis.

Specifically, the outer tube is made of transparent or semitransparent plastic materials.

Specifically, the widest dimension of the cross section of the eye-catching area is larger than that of the cross section of the taper small end of the outer tube, and the shape of the cross section of the eye-catching area comprises a circular ring shape, an outer ellipse and an inner circle shape, an inner ellipse and an outer ellipse shape, a flattened and overlapped shape and a circular ring local flattened shape.

In particular, the eye-catcher is a single eye-catcher, or a plurality of single eye-catchers, or a single multi-eye catcher.

Specifically, the outer surface of the tapered outer tube is provided with a small end with a small outer diameter and a large end with a large outer diameter along the axis direction, the large end and the small end are in smooth transition along the axis direction, and the smooth transition mode comprises linear transition, circular arc transition, combined curve transition and combined linear transition; the ratio of the minimum width dimension of the taper region to the large end dimension of the taper region is 60-80%.

Specifically, the eye-catching region may be a single eye occupying the most pointed end of the whole floating eye, that is, a single eye-catching region; or the plurality of single eye striking areas respectively occupy a plurality of floating eyes at the tip; or longer highlight regions having at least two floats thereon, thereby forming a multi-highlight region.

Specifically, the outer tube is a single integrally formed tube made of a PC material, or a plurality of tubes can be spliced and fixed on the outer side of the optical fiber through glue, and the position of the splicing part is located in the width range of the light shading area of the optical fiber.

Specifically, the optical fiber and the outer tube are sequentially detachably connected to the protective sleeve, the float tail seat, the sealing ring and the LED light-emitting element. The optical fiber rod is made of light guide materials including PMMA materials. The float body is fixedly connected with the float body inner sleeve and the float foot in sequence and is integrally formed through viscose.

Compared with the prior art, the beneficial effects of the utility model are that:

the outer surface of the outer pipe provided by the utility model is even, no matter the outer pipe is a parallel straight pipe or a taper pipe, even if the outer pipe is a striking outer pipe, the striking area of the outer pipe is mainly used for facilitating the observation of human eyes, and the fish eating mouth is mainly a taper area in the judgment of participation, therefore, the outer pipe provided by the utility model is smoother in the water inlet and outlet processes; on the other hand, the outer tube of the utility model has the same pattern of the float mesh printing as the conventional daily float, and the operation habit of the fishing man is not changed basically when the fishing is carried out in the daytime; on the other hand, due to the adoption of the combined use scheme of the internal optical fiber shading area and the external outer tube color separation area, which is firstly provided by the utility model, the spacing distance between the luminous floating eyes can be well controlled during night fishing, and the luminous floating eyes can be clearly seen during night fishing; on the other hand, aiming at the distance between the float corresponding to different fishing rod lengths and a fisherman in water, the luminous float mesh interval can be designed in a matching way, and on the premise of meeting the requirement of clearly distinguishing the float mesh in fishing, the luminous float mesh interval is reduced as much as possible, so that the sensitivity is ensured; in another aspect, the utility model discloses the scheme realizes that multiple electron float morphological change such as tapering tail, striking tail, flat tail through changing integrated into one piece's outer tube shape, realizes being equal to the multiple selection that conventional daily use was floated, has enlarged the product kind that the electron was floated, satisfies different fishing scenes and fishing demand.

Drawings

FIG. 1 is a schematic structural view of a conventional daily-use general float

FIG. 2 is a schematic view of a conventional electronic float

FIG. 3 is a schematic view of the luminescence of the conventional electronic float

FIG. 4 is a schematic view of a dual-purpose float for day and night in the prior art

FIG. 5 is a first luminous illustration of a dual-purpose float for day and night in the prior art

FIG. 6 is a schematic diagram of a second light-emitting device for a day-night dual-purpose float in the prior art

FIG. 7 is an overall composition diagram of a day and night dual-purpose electronic float

FIG. 8 is an overall explosion diagram of a day and night dual-purpose electronic float

FIG. 9 is an overall cross-sectional view of a day and night dual-purpose electronic float

FIG. 10 is a design diagram of an optical fiber of an outer tube of the first embodiment of a day and night dual-purpose electronic float

FIG. 11 is a view of the optical fiber combination of the outer tube of the first embodiment of the day and night dual-purpose electronic float

FIG. 12A is a diagram showing a combination of a shading area and a color separation area of a day-night dual-purpose electronic float, in which the shading area and the color separation area are completely overlapped

FIG. 12B is a diagram showing a day and night dual-purpose electronic float with two completely overlapped color-separating regions in the shading region of the first embodiment

FIG. 12C is a partially overlapped view of the color separation region of the shading region of the first embodiment of a day and night dual-purpose electronic float

FIG. 12D is a matching view of the first embodiment of the shading area and the color separation area of the day and night dual-purpose electronic float

FIG. 13A is a view showing a light-emitting effect of the first embodiment of a day and night dual-purpose electronic float with a completely overlapped color-separating region in the shading region

FIG. 13B is a schematic view showing two lights emitted from the light shielding region and the color separation region of the day and night dual-purpose electronic float with two completely overlapped colors according to the first embodiment

FIG. 13C is a schematic view showing a light-shielding region and a color-separating region of a day-night dual-purpose electronic float with partially overlapped light emission in the first embodiment

FIG. 13D is a schematic view showing the splicing luminescence of the color separation region in the shading region of the day and night dual-purpose electronic float according to the first embodiment

FIGS. 14 and 15 are a day and night comparison chart of the first embodiment of the day and night dual-purpose electronic float

FIG. 16 is a design diagram of an outer tube optical fiber of a second embodiment of a day and night dual-purpose electronic float

FIG. 17 is a diagram of the combination of the outer tube and the optical fiber of the second embodiment of a day and night dual-purpose electronic float

FIGS. 18 and 19 are a day and night comparison chart of a second embodiment of a day and night dual-purpose electronic float

FIG. 20 is a design diagram of an optical fiber of an outer tube of a third embodiment of a day and night dual-purpose electronic float

FIG. 20A is a sectional view of a striking area of a third embodiment of a day and night dual-purpose electronic float

FIG. 21 is a third embodiment of an optical fiber combination diagram of an outer tube of a day and night dual-purpose electronic float

FIG. 22 is a day and night comparison diagram of a third embodiment of a day and night dual-purpose electronic float

FIG. 23 is a day and night comparison diagram of a fourth embodiment of a day and night dual-purpose electronic float

FIG. 24 is a day and night comparison chart of a fifth embodiment of the day and night dual-purpose electronic float

FIG. 25 is a schematic diagram showing the composition of an outer tube of a sixth embodiment of a day and night dual-purpose electronic float

FIGS. 26 and 27 are a day and night comparison chart of a sixth embodiment of a day and night dual-purpose electronic float

1. An outer tube; 2. an optical fiber; 3. a protective sleeve; 4. a bleaching tail seat; 5. a seal ring; 6. an LED light emitting element; 7. a battery; 8. A floating body inner sleeve; 9. floating; 10. floating feet; 601. an LED lamp; 602. an LED lamp holder; 110. a first outer tube; 210. a first optical fiber; 111. a color separation area; 112. a color zone A; 113. a color zone B; 211. a light-shielding region 211; 212. a color zone A'; 213. A color zone B'; 214. the rest shading area; 215. an optical fiber light-transmitting region; 120. a second outer tube; 220. a second optical fiber; 130. a third outer tube; 230. a third optical fiber; 330. a highlight area; 140. a fourth outer tube; 150. a fifth outer tube; 160. a sixth outer tube; 160-1, sixth outer tube 1; 160-2, sixth outer tube 2; 160-3, sixth outer tube 3.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention, i.e., the described embodiments are only some, but not all embodiments of the invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiment of the present invention, all other embodiments obtained by the person skilled in the art without creative work belong to the protection scope of the present invention.

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations where mutually exclusive features are expressly stated.

The following, with reference to the drawings and the detailed description, further description of the present invention is made:

a day and night dual-purpose electronic buoy is shown in figures 7, 8 and 9 and comprises a floating tail assembly (1000) with a built-in LED light-emitting assembly (6), a buoy body assembly (2000) and a battery (7) which can be conveniently arranged into the floating tail assembly and is communicated with the LED light-emitting element (6). Float body subassembly (2000) by float body (9), float body endotheca (8) and float foot (10) and constitute, set up through viscose integrated into one piece. The float tail assembly (1000) is composed of an outer tube (1), an optical fiber (2), a protective sleeve (3), a float tail seat (4), an LED light-emitting group (6) and a sealing ring (5) sleeved on the float tail seat. The protective sleeve (3) is made of soft materials and fixed on the bleaching tailstock (4) through viscose, and can also be directly formed on the bleaching tailstock (4) through secondary injection molding. The optical fiber (2) and the outer tube (1) are inserted into the bleaching tail seat (4), and the outer tube (1) is sleeved on the outer side of the optical fiber (2). The LED light-emitting group (6) is composed of an LED lamp (601) and an LED lamp holder (602). The optical fiber (2) is made of a light guide material, such as PMMA (polymethyl methacrylate) material in particular, and the outer tube (1) is made of transparent plastic or semitransparent plastic material, such as PC material in particular.

Fig. 10 shows the design features of the first embodiment of the present invention corresponding to the first outer tube (110) and the first optical fiber (210), specifically, the first outer tube (110) is a hollow outer tube and is sleeved outside the first optical fiber (210), the outer surface of the first outer tube (110) is sequentially coated with a plurality of color regions from the floating tail tip to the floating body (9), i.e., a color region a (112), a color separation region (111), and a color region B (113), the color separation region (111) is between the color region a (112) and the color region B (113), forming a single outer tube color region combination; the outer tube color zone combination is increased along drifting tail axis direction circulation in proper order, forms a plurality of outer tubes and floats the mesh, color separation zone (111) on first outer tube (110) have width W (1), and is preferred, and W (1) is 2 to 4 millimeters, the width of color separation zone A (112) or color separation zone B (113) is obviously than color separation zone (111) is wide, color separation zone (111) mainly play the color interval effect, color separation zone A (112) with color separation zone B (113) colour nonconformity. The outer surface of the first optical fiber (210) is coated with a plurality of color areas which are sequentially distributed into a color area A '(212), a shading area (211) and a color area B' (213); the light shielding area (211) is arranged between the color area A '(212) and the color area B' (213) to form a single optical fiber color area combination; the color area combinations of the single optical fibers are sequentially and circularly increased along the axis direction to form a plurality of optical fiber bleaching meshes; the outer surfaces of the color area A '(212) and the color area B' (213) are processed for the second time to generate a plurality of light transmission areas (215), and the LED lamp (601) emits light and then irradiates the light to the outside through the light transmission areas (215); the number of the corresponding optical fiber color area combinations of the optical first optical fiber (210) is designed according to the drift tail length, and the rest surface area is processed according to the same surface process of the light shielding area (211) to form a rest light shielding area (214). The materials attached to the outer surfaces of the light-shielding area (211) and the residual light-shielding area (214) on the first optical fiber (210) can block or reduce the light emitted by the LED from irradiating outwards in the areas of the light-shielding area (211) and the residual light-shielding area (214), the light-shielding area (211) has a width W (2), and the size relation of the color separation area W (1) is W (2) ≧ W (1).

The color area a 'and the color area B' of the first optical fiber (210) may or may not be the same as the color area a and the color area B of the first outer tube (110), and the color area a 'and the color area B' may not be colored.

Fig. 11 illustrates the combined effect of the first optical fiber (210) and the first outer tube (110) when installed to form a floating tail assembly according to the first embodiment of the present invention. Further, the first outer tube (110) is a cylindrical straight tube with the same outer diameter Da1 and the same inner bore diameter Da1, the inner bore diameter Da1 is slightly larger than the outer diameter of the first optical fiber (210) and has a smaller gap, and the first outer tube (110) is subjected to a head sealing process near the tip. As further shown in fig. 12A, 13A, 12B, 13B, 12C, 13C, 12D, and 13D, the axial position relationship between the color separation region (111) on the first outer tube (110) and the light-shielding region (211) on the first optical fiber (210) may be in four combinations, one of which is that the color separation region (111) is completely contained in the light-shielding region (211), and the front and rear end points of the color separation region (111) and the light-shielding region (211) have respective distances LA and LB to form a complete overlap, and at this time, the interval width W (3) of the whole night light drift is W (2); in another combination mode, one end of the color separation area (111) is aligned with one end of the shading area (211), the other end of the color separation area is contained in the shading area (211) to form complete overlapping, and the interval width W (3) of the whole night luminous bleaching purpose is equal to W (2); another combination is that the color separation area (111) and the shading area (211) are partially overlapped, and the spacing width W (2) < W (3) < W (2) + W (1) of the whole night luminous bleaching object is formed; in another combination, one end of the color separation area (111) and one end of the shading area (211) are aligned and combined in an end-to-end splicing mode, and at the moment, the interval width W (3) of the whole night luminous bleaching purpose is W (2) + W (1). As can be understood by those skilled in the art, the four different combination modes have different expression effects corresponding to the interval width of the luminous bleaching at night and the length of a single bleaching eye.

Further referring to fig. 14, 15, can clearly see, when the cursory was used daytime, inside optic fibre was luminous, and the fishing people carries out the fishing according to the mesh of floating of outer tube, as before, the utility model discloses the scheme provides a cursory outer tube is floated unanimously with current day, and the spacing distance between the floating mesh is color space width W (1), consequently satisfies the operation requirement of the cursory of fishing people. When the cursory use at night, the cursory visual effect of outer tube weakens, mainly rely on inside optic fibre luminous the new luminous mesh that floats of formation this moment, and luminous mesh interval W (3) of floating this moment according to aforementioned several kinds of compound effects, W (2) are less than or equal to W (3) are less than or equal to W (2) + W (1), thereby luminous mesh interval that floats has been increaseed, it floats the mesh quantity variation to be convenient for observe luminous the luminous clear discernment of mesh at night, and the size of control W (3) that can be fine, in order to satisfy the fish at night, according to the float distance angle fish the distance of fish person far and near, the adjustment the size of W (3), realize the different mesh interval effect that floats. Therefore, the combined technical characteristics of the shading area and the color separation area of the utility model are adopted, and the same buoy can be better used day and night.

Fig. 16 and 17 show the outer tube fiber design and combined structure of the second embodiment of the present invention, compare the scheme proposed by the first embodiment, the second embodiment provides a conical second outer tube (120) with gradually changed outer diameter and unchanged inner bore diameter, the outer surface of the second outer tube (120) has the small end of the small outer diameter Db1 and the big end of the large outer diameter Db2 along the axis direction, the big end reaches the small end is in smooth transition along the axis direction, the smooth transition mode includes straight line transition, circular arc transition, combined curve transition, combined straight line transition, thereby forming a conical outer tube with a conical outer surface. The transition area between the corresponding big end of second outer tube (120) and the tip is the tapering district, the outer tube has except that the tapering district, or includes the primary dimension district that external diameter size is unanimous. Fig. 18 and 19 show day and night use effects of the day and night dual-purpose variable-floating electronic buoy with the tapered outer tube. The ratio of the minimum width Db1 of the taper region to the large end Db2 of the taper region is 60-80%.

Fig. 20 shows the design and combination structure of the outer tube optical fiber according to the third embodiment of the present invention, compared with the solution proposed by the second embodiment, the third embodiment provides a third outer tube (130) with gradually changed outer diameter and a striking area at the tip, the third outer tube (130) is designed with a striking area (330) at the tip of the tail, as shown in fig. 20A, the cross-sectional shape of the striking area (330) can be circular ring type, outer ellipse inner circle type, inner and outer ellipse type, flattened superposition type, circular ring local flattened type, etc., the widest dimension of its main characteristic cross-section is obviously larger than the dimension of the outer diameter Dd1 (or widest dimension) of the small end of the outer surface of the third outer tube (130), forming a striking floating, and the striking area is the third outer tube (130) formed integrally; if the highlighted area is circular as shown in fig. 20, the maximum dimension is the outer diameter Dd2 of the large end of the third outer tube (130). The embodiment shows that the eye-catching region (330) is a single eye, i.e. the whole of the first eye of the tip is the eye-catching region, and the color separation region is outside the eye-catching region. Fig. 22 shows the daily effect of the third embodiment with a single eye-catcher.

Fig. 23 shows the day and night dual-purpose variable-purpose electronic floating effect of the fourth embodiment having two single eye-catching regions, compared to the third embodiment, the fourth embodiment provides a fourth outer tube (140) having 2 single eye-catching regions, i.e., a first single eye-catching region and a second single eye-catching region, the first single eye-catching region and the second single eye-catching region constituting first and second floating eyes from the tip, and a color-separating region interposed between the eye-catching regions; multiple monocular highlighting areas may be desired or designed.

Fig. 24 shows the day and night dual-purpose variable-purpose electronic floating day and night use effect of the fifth embodiment with a multi-eye region, compared with the third embodiment, the fifth embodiment provides the fifth outer tube (150) with a longer eye region length and two or more than two floating eyes in the eye region, namely one or more color separation regions in the eye region.

The foregoing embodiments all show the scheme of integrally formed outer tubes, and in the scope of the present invention, the outer tube or the outer tubes are formed by splicing a plurality of outer tubes, as shown in fig. 25, a sixth outer tube (160) is formed by a sixth outer tube 1(160-1), a sixth outer tube 2(160-2), a sixth outer tube 3(160-3), etc. With continued reference to fig. 26 and 27, the combined sixth outer tube (160) still has the bleaching scheme 6 with different color regions arranged alternately, and is characterized in that the shading region of the optical fiber still covers the splicing positions of the outer tubes, so that the night fishing requirement can still be met when the combined sixth outer tube is used at night.

Compared with the prior art, on one hand, the outer surface of the outer pipe provided by the utility model is uniform, no matter the outer pipe is a parallel straight pipe or a taper pipe, even if the outer pipe is a striking outer pipe, the striking area of the outer pipe is mainly used for facilitating the observation of human eyes, and the fish eating mouth is mainly a taper area in the judgment, so the outer pipe provided by the utility model is smoother in the water inlet and outlet processes; on the other hand, the outer tube of the utility model has the same pattern of the float mesh printing as the conventional daily float, and the operation habit of the fishing man is not changed basically when the fishing is carried out in the daytime; on the other hand, due to the adoption of the combined use scheme of the internal optical fiber shading area and the external outer tube color separation area, which is firstly provided by the utility model, the spacing distance between the luminous floating eyes can be well controlled during night fishing, and the luminous floating eyes can be clearly seen during night fishing; on the other hand, aiming at the distance between the float corresponding to different fishing rod lengths and a fisherman in water, the luminous float mesh interval can be designed in a matching way, and on the premise of meeting the requirement of clearly distinguishing the float mesh in fishing, the luminous float mesh interval is reduced as much as possible, so that the sensitivity is ensured; in another aspect, the utility model discloses the scheme realizes that multiple electron float morphological change such as tapering tail, striking tail, flat tail through changing integrated into one piece's outer tube shape, realizes being equal to the multiple selection that conventional daily use was floated, has enlarged the product kind that the electron was floated, satisfies different fishing scenes and fishing demand.

The above embodiments, except describing the eye-catching area and showing many clocks cross-sectional shape through the illustration, and the outer tube is described as the ring type as a whole, and those skilled in the art can understand, in the utility model discloses the scheme, the cross-sectional shape of outer tube can be other cross-sectional shapes except the ring type equally, like outer ellipse inner circle, inside and outside ellipse type, flatten the superimposed type, the local flattening type of ring, can realize these technical schemes all through certain technological means and be in the technical scope of the utility model.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention. In the description of the present invention, it should be noted that the terms "top", "bottom", "one side", "the other side", "front", "back", "middle part", "inside", "top", "bottom", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, which is only for the convenience of description and simplification of the description, but does not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Claims (10)

1. The utility model provides a day night double-purpose electron is cursory, includes floats tail subassembly, battery and floats the body subassembly, it can dismantle the connection in proper order to float the tail subassembly the battery with float the body subassembly, it includes outer tube, optic fibre, protective sheath, LED light emitting component and sealing washer to float the tail subassembly, its characterized in that:

1) the outer tube is in a hollow tube shape, and the optical fiber is inserted into an inner hole of the outer tube to form an internal and external assembly relation;

2) the outer surface of the outer tube is coated with a plurality of color areas which have different colors and are alternately arranged to form an outer tube floating mesh;

3) a plurality of spaced light shielding areas are attached to the outer surface of the optical fiber, and the light shielding areas can block or reduce the light of the LED from irradiating outwards in the light shielding areas;

4) the outer pipe is a parallel straight pipe with the unchanged inner diameter and outer diameter, or the outer pipe is a taper outer pipe with the gradually increased outer diameter, or the outer pipe is a striking taper pipe with a striking area at the tip of the taper pipe.

2. The dual-purpose electronic float of day and night according to claim 1, characterized in that:

a color separation area is arranged between two adjacent color areas on the outer tube bleaching mesh, the color of the color separation area is a dark color system and plays a role in color separation, the axial width of the color separation area is W (1), and the size of the W (1) is 2-4 mm;

the width dimension W (2) of the optical fiber shading area has the dimension relation that W (2) is more than or equal to W (1);

and viewed in radial projection, the axial directions of the color separation area width W (1) of the outer tube and the shading area width W (2) have a complete overlapping or partial overlapping or end-to-end splicing position relationship.

3. The dual-purpose electronic float of day and night according to claim 1, characterized in that: and a light transmitting area is manufactured on the outer surface outside the optical fiber shading area through secondary processing, and the LED light irradiates outwards through the light transmitting area to emit light.

4. The dual-purpose electronic float of day and night according to claim 1, characterized in that: the outer surface outside the optical fiber shading area is coated with a color area to form an optical fiber floating eye.

5. The dual-purpose electronic float of day and night according to claim 1, characterized in that: the outer pipe is made of a single material which is integrally formed.

6. The dual-purpose electronic float of day and night according to claim 1, characterized in that: the outer tube is also spliced by a plurality of tubes and is fixed on the outer side of the optical fiber through glue, and the position of the spliced position is located in the width range of the light shielding area of the optical fiber along the axis.

7. The dual-purpose electronic float of day and night according to claim 1, characterized in that:

the outer tube is made of transparent or semitransparent plastic materials.

8. The dual-purpose electronic float of day and night according to claim 7, characterized in that: the widest size of the cross section of the eye-catching area is larger than that of the cross section of the taper small end of the outer tube, and the shape of the cross section of the eye-catching area comprises a circular ring shape, an outer ellipse and an inner circle, an inner ellipse and an outer ellipse, a flattening and overlapping shape and a circular ring local flattening shape.

9. The dual-purpose electronic float of day and night according to claim 8, characterized in that: the eye-catcher is a single monocular eye-catcher, or a plurality of monocular eye-catchers, or a single multi-eye catcher.

10. The dual-purpose electronic float of day and night according to claim 1, characterized in that: the outer surface of the taper outer pipe is provided with a small end with a small outer diameter and a large end with a large outer diameter along the axis direction, the large end and the small end are in smooth transition along the axis direction, and the smooth transition mode comprises linear transition, circular transition, combined curve transition and combined linear transition; the ratio of the minimum width dimension of the taper region to the large end dimension of the taper region is 60-80%.

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