CN109644957B - Hollow row Shui Xingmu floats tail and sidestream cursory - Google Patents

Abstract

The invention discloses a hollow row Shui Xingmu floating tail, which is characterized by comprising a floating tail body with a hollow inside, wherein floating meshes are arranged on the outer wall of the floating tail body, an interval mesh is arranged between two adjacent floating meshes, the color of the interval mesh is different from that of the floating meshes, a plurality of water holes communicated with the inside of the floating tail are arranged on the floating tail body, the water holes are uniformly distributed in a staggered manner along the axial direction and the circumferential direction of the floating tail body, a floating tail connecting cap is connected at the bottom of the floating tail body, and the floating tail connecting cap and the floating tail body are detachably connected or integrally formed; through redesigning the mechanical analysis of the buoy and the drift tail of the model Ji Suandui, the drift tail adopting the hollow, thin-wall and drainage through hole structure greatly improves the displacement sensitivity and the descending (speed) sensitivity of the fishing group system, thereby meeting the requirements of deep fishing and long fishing.

Description

Hollow row Shui Xingmu floats tail and sidestream cursory

Technical Field

The invention belongs to the technical field of fishing, and particularly relates to a hollow row Shui Xingmu float tail and a side-stream float.

Background

In fishing sports, particularly bench fishing, small fish are required to be fished by a buoy with a small tail diameter, particularly when fishing light-mouthed fish in winter. If a coarse float with a floating tail is used and a fishhook is generally smaller, the coarse float can not meet the requirement of the hook, and the weak force consumption of sucking the bait of the fish is larger on the buoyancy increment of the float descending at the coarse float tail, so that the descending distance of the floating tail is reduced, and the descending speed of the floating tail is also slowed down.

From physical and mechanical analysis, the force of the fish sucking bait is finally equal to the buoyancy increment of the water received by the tail-floating volume in the range of the length of the fish sucking bait to drive the eyes to descend. If the tail is too thick and the mouth is light, the force of sucking the bait can only be used for overcoming the buoyancy increment of the water received by the tail in the range of the short-length descending of the float, namely, the float can only be slowly descended by a small length, so that the effective mouth can not be distinguished by the fisher in the process of the slow and short-length descending of the float. For fishing light-mouth fish, the sensitivity of the fishing group is greatly reduced by the rough tail float. Therefore, the fine tail float is necessary. However, in early winter, deep fishing is required. When the fishing is far, the float with small tail diameter is difficult to see the clear float phase, and the sensitivity of not seeing the clear float phase is ineffective.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a hollow row Shui Xingmu float tail and a side-stream float, which are beneficial to fishing a long-distance float and can meet the requirement of keeping enough sensitivity including fishing a small fish with a light mouth; the technical scheme adopted for achieving the purpose is as follows:

the utility model provides a Shui Xingmu floats the tail, is including inside hollow tail body that floats, is equipped with on the tail body outer wall that floats and floats the mesh, is equipped with the interval mesh between two adjacent floating meshes, interval mesh colour is different with float the mesh colour, is equipped with a plurality of limbers that are linked together with float the tail inside on the tail body that floats, and a plurality of limbers are along floating tail body axial and circumference evenly staggered, are connected with the tail connecting cap that floats in tail body bottom, float and be detachable connection or integrated into one piece preparation between the tail connecting cap and the tail body that floats.

Preferably, the plug hole for connecting the floating body is formed in the floating tail connecting cap, a silica gel layer is arranged in the plug hole, the floating tail connecting cap is a shell with a cavity inside, a filling body is filled in the cavity inside the floating tail connecting cap, and the material of the filling body is the same as that of the filling material in the floating body.

Preferably, the floating tail connecting cap comprises a transition sleeve integrally formed with the bottom of the floating tail body, a water-through support frame is arranged in the bottom of the sleeve, a water-through port is arranged on the water-through support frame, a connecting sleeve is coaxially fixed on the water-through support frame, and the outer diameter of the connecting sleeve is smaller than that of the transition sleeve.

Preferably, a hydrophobic film is coated on the inner wall of the float tail body.

Preferably, the wall thickness of the float tail body is not more than 0.15 millimeter, and the interval target length is not more than half of the float target length.

Preferably, the water through holes are formed by digging out part of the side wall on the interval mesh, and the area of the dug part of the side wall is larger than half of the surface area of the interval mesh.

Preferably, the automatic floating device further comprises a floating body, wherein a transition floating tail is arranged at the top of the floating body, floating feet are arranged at the bottom of the floating body, the transition floating tail is inserted on the floating tail connecting cap, and the outer diameter of the floating tail body is larger than that of the transition floating tail or the floating feet.

Preferably, the floating body is further included, the floating foot is arranged at the bottom of the floating body, the top of the floating body is coaxially fixed on the floating tail connecting cap, and the outer diameter of the floating tail body is larger than that of the floating foot.

The invention has the beneficial effects that: through redesigning the mechanical analysis of the buoy and the drift tail of the model Ji Suandui, the drift tail adopting the hollow, thin-wall and drainage through hole structure greatly improves the displacement sensitivity and the descending (speed) sensitivity of the fishing group system, thereby meeting the requirements of deep fishing and long fishing. On the other hand, through setting the tail connection cap to the structural style of transition sleeve, realized that rivers flow in from the tail bottom of floating and flow in and (smoothly go in and out) float in the tail and reduced water (leading in water) resistance to further improved the displacement sensitivity and the decline (speed) sensitivity of fishing group system.

The tail of the float can also be manufactured into a series of side-stream floats by adjusting the outer diameter size and the wall thickness of the hollow float, thereby meeting the fishing requirements of different hook-type and far-vision floats. The fish mouth signal amplifier can also be manufactured into a pluggable eye-float tail which is matched with other finished floats to be used, and the fish mouth signal amplifier is manufactured into a traditional integrated float with a part of fine solid eye-float tail and belly-float feet to be a side-flow float.

Drawings

FIG. 1 is a schematic diagram of the hollow row Shui Xingmu drift tail structure in embodiment 1;

FIG. 2 is a schematic illustration of the structure of a sidestream float in example 1;

FIG. 3 is a schematic view showing the structure of a hollow row Shui Xingmu drift tail in embodiment 2;

FIG. 4 is a schematic view of the structure of a sidestream float in example 2;

FIG. 5 is a schematic view showing the structure of a hollow row Shui Xingmu drift tail in embodiment 3;

FIG. 6 is a schematic view of the water passing support stand of FIG. 5;

FIG. 7 is a schematic view showing the structure of a sidestream float in example 3;

FIG. 8 is a graph of the float mechanics analysis and calculation of the present invention.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

Specific example 1:

as shown in fig. 1, a hollow row Shui Xingmu floats the tail, including the inside hollow body 107 that floats, be equipped with on the outer wall of body 107 that floats and float mesh 101, be equipped with interval mesh 102 between two adjacent float mesh 101, interval mesh 102's colour is different with float mesh 107's colour, be equipped with a plurality of limbers 103 that are linked together with the inside of floating the tail on body 107 that floats, a plurality of limbers 103 are evenly staggered along body 107 axial and circumference, are connected with and float tail connecting cap 104 in body 107 bottom that floats, float and be detachable connection or integrated into one piece preparation between tail connecting cap 104 and the body 107 that floats.

The floating tail connecting cap 104 is provided with a plug hole 105 for connecting the floating body 3, a silica gel layer is arranged in the plug hole 105, the floating tail connecting cap 104 is a shell with a cavity inside, the cavity inside the floating tail connecting cap 104 is filled with a filling body 106, and the material of the filling body 106 is the same as that of the floating body.

Since the drag force when the body of the tail float 107 descends is increased due to the existence of the surface tension action of the water body in the body of the tail float 107, in order to reduce the drag force action, a hydrophobic film is coated on the inner wall of the body of the tail float 107.

To further increase the displacement sensitivity and the speed sensitivity of the floating tail of the present invention, the wall thickness of the floating tail body 107 is not more than 0.15 mm, and the length of the spacer mesh 102 is not more than half the length of the floating mesh 101. On the other hand, in order to ensure the integrity and the convenient observability of the floating mesh 101, the water through holes 103 are arranged on the interval mesh 102, that is, the water through holes 103 are formed by digging out part of the side wall on the interval mesh 102, and the area of the part of the side wall which is dug out is larger than half of the surface area of the interval mesh 102.

As shown in fig. 2, a sidestream float with the above-mentioned tail, including a float body 3, be equipped with transition tail 2 that floats at the top of the float body 3, be equipped with the foot 4 that floats in the bottom of the float body 3, transition tail 2 peg graft on the tail connecting cap 104 that floats, the external diameter of the tail body 107 that floats is greater than the external diameter that transition floats tail 2 or floats foot 4.

Specific example 2:

the difference from embodiment 1 is the structural form of the tail connection cap 104 and the connection manner between the tail 1 and the body 3. As shown in fig. 3 and 4, an arc notch 107 matched with the top of the float body 3 is arranged at the bottom of the plugging hole 105, a plug connector matched with the plugging hole 105 is arranged at the top of the float body 3, and the plug connector is inserted into the plugging hole 105, and the top of the float body 3 is adhered to the arc notch 107, so that quick in-place floating is realized.

Specific example 3:

the difference from embodiment 1 and embodiment 2 is the structural form of the tail connection cap 104 and the connection manner between the tail 1 and the float 3. As shown in fig. 5 to 7, the tail-floating connection cap comprises a transition sleeve 109 integrally formed with the bottom of the tail-floating body 107, a water-passing support 108 is arranged in the bottom of the sleeve 109, a water-passing port 111 is arranged on the water-passing support 108, a connection sleeve 112 is coaxially fixed on the water-passing support 11, and the outer diameter of the connection sleeve 112 is smaller than that of the transition sleeve 107.

Alternatively, when combined with a conventional float, the transition sleeve 112 is connected to the transition tail of the float, or the transition tail may be directly and fixedly connected to the water-passing support 108.

The mechanical analysis of the present invention is as follows:

as shown in fig. 8, the reference numerals in the figure are: g _{Bleaching device} -float body dead weight; g _Lead -lead skin weight; g _{Bait suspension} -a weight of suspended bait; m is M _{Initially, the method comprises} Initial fishing (i.e. initial float length); f (F) _{Float 1} -the buoyancy of the water is withstood during the initial fishing;

F _{suction pipe} Force of sucking the bait by the fish: deltaF _{Floating device} -the force of the fish sucking the bait causes the body within the range of the number of eyes of the eye drop to be subjected to the buoyancy increase of the water when the eye drop is of the final length; m is M _{Terminal (A)} -the force of sucking the bait by the fish and the buoyancy increase of the floating water are maintained at ordinary time to see the number of floating eyes; d (D) ₁ -outer diameter of the lateral flow float; d (D) ₂ -the diameter of the float tail of a solid float, i.e. the equivalent diameter, which is the same as the circular ring area of the cross section of the lateral flow float tail; d (D) ₃ -a solid float diameter identical to the lateral float outer diameter; the force of fishing bait on the delta M-side flow float and the fine tail float with equivalent diameter and the float eye drop number when the buoyancy increment of the float water is kept at ordinary times; r-hollow inner radius of lateral flow float; s-side flow float wallThickness; deltaM ₁ The force of sucking the fish bait and the buoyancy increment of the floating water are kept at the same level, and the number of the floating eyes of the solid float with the same outer diameter as that of the side-stream float is reduced.

It is assumed that the fish is under a constant force F for a period of time _{Suction pipe} To suck the bait. F (F) _{Suction pipe} Resulting in lowering of the fishing line. The water inlet volume of the float body at the float eye is increased when the fishing group descends, so that the whole fishing group is subjected to the increased buoyancy of the water. When the buoyancy of the water is increased and the force of the fish sucking bait is kept flat, the fishing group descends to the final position and stops descending to be in a static state. At this time, the float (specifically, the float at the eye) receives the buoyancy increment Δf of water _{Floating device} Force F equal to the suction force of the fish _{Suction pipe} . Namely:

F _{suction pipe} ＝△F _{Floating device}

That is, the force F of attracting the fish for the final length of the drift, i.e., the displacement sensitivity of the fishing line system _{Suction pipe} Only used for 'antagonizing' the buoyancy increment DeltaF suffered by the eye-bleaching body within the eye-bleaching descending length DeltaM _{Floating device} 。

The fish is forced with a constant force F during a certain period of time _{Suction pipe} The assumption that the bait is sucked is important. The sensitivity of the fishing group system is changed from chaos to clarity. Even though the force with which the fish draws in bait is not constant in practice, the force with which it draws in the bait is within a certain range for a certain size and variety of fish. The length of the drift down resulting from the ingestion of a bait by a particular fish is limited to analyze, and such assumptions are also consistent with statistical principles, and thus scientific.

And the fishing group still receives the resistance of water in the process that the fish sucks the bait to cause the fishing group to descend. The water resistance affects the descending speed of the fishing group, namely, the descending speed of the fishing group is slowed down. However, since the group is stationary at the time of initial fishing, force F of the fish sucking the bait _{Suction pipe} Delta F of buoyancy of water to the float _{Floating device} When the fishing rod is held at normal time, the fishing group is still, and no water resistance exists at the moment. Therefore, the final descent length of the fishing line is independent of the water resistance.

The sensitivity of the whole fishing group system with reasonable collocation of the lead-floating hook baits can be divided into two types. One type is speed sensitivity. Characterized by the speed characteristics of the fish sucking the bait to cause the fishing group to descend. The other is displacement sensitivity. Characterized by the displacement (length, mesh) characteristic of the fish sucking the bait to cause the lowering of the fishing group. From the above analysis, it can be seen that the water resistance only affects the speed sensitivity of the fishing line system, and has no effect on displacement sensitivity. Therefore, the water resistance is not required to be considered when the displacement sensitivity of the fishing group is examined.

Force F of sucking bait _{Suction pipe} Delta F of buoyancy of water to the float _{Floating device} When the fishing rod is kept at rest, the fishing rod (the eye-floating position) reaches the maximum displacement delta M. While the buoyancy increment DeltaF _{Floating device} ＝ρgV _{Row of rows} ＝ρgS ₁ *△M。

S ₁ The cross-sectional area of the float mesh which participates in the volume of the discharged water when the float mesh descends. For sidestream bleaching, it is the area of the circular ring of cross section, equal to pi { (D1/2) 2-R2}: for cylindrical solid floats, the area of the cross-sectional circle is that of pi (D ₂ /2) ² And pi (D) ₃ /2) ² 。

So there are: f (F) _{Suction pipe} ＝△F _{Floating device} ＝ρgπ{(D ₁ /2) ² -R ² }*△M＝ρgπ(D ₂ /2) ² △M＝ρgπ(D ₃ /2) ² △M ₁

Due to the diameter D ₂ The solid float of (2) is an equivalent diameter float of a lateral flow float having an outer diameter D1, so that the final length of the float drop caused by sucking the bait on the same fish on both floats is the same, and is ΔM. I.e. thickening the outer diameter to D ₁ Is as small as D in diameter and displacement sensitivity of lateral flow drift ₂ The displacement sensitivity of the solid floats of (a) is the same. While the lateral flow float has a much larger outer diameter. Therefore, the effects of thickening and bleaching eyes to make vision clear and maintaining enough displacement sensitivity can be achieved. In fact, the lateral flow drift is reduced in speed sensitivity compared with a solid tail drift of equivalent diameter due to the water resistance of the lateral flow drift small holes for water inlet and drainage. However, because the water is nearly fed and drained, the water-passing distance is extremely short compared with the water-passing drainage, and the open pore volume also increases the displacement sensitivityDegree, which condition ensures the displacement sensitivity of the lateral flow float and the diameter is as small as D ₂ The solid drift of the water inlet and outlet holes is the same, and the water resistance can be further reduced by properly enlarging the size of the water inlet and outlet holes, so that the water inlet and outlet holes have good thickening and protecting effects.

An outer diameter of D ₁ Is of the same diameter D ₃ Compared with solid drift due to D ₁ ＝D ₃ They have the same visual clarity. However, as can be seen from the formula (1),

π(D ₂ /2) ² △M＝π(D ₃ /2) ² △M ₁

△M/△M ₁ ＝(D ₃ /D ₂ ) ²

because of D ₂ For side-stream drift D ₁ Has the same displacement sensitivity, so D is used ₂ Instead of lateral flow drift.

That is, the same fish will draw the bait, the ratio of the reduced length of the shade of the sidestream float to the solid shade of the same outside diameter (typically displacement sensitivity) is equal to the square of the reciprocal of the ratio of the equivalent diameter of the sidestream float to the diameter of the solid shade of the same outside diameter-! If the equivalent diameter D of the sidestream drift ₂ Reduced to an outer diameter D ₁ Is increased by a factor of four. Therefore, the wall thickness of the lateral float is reduced as much as possible, so that the equivalent diameter of the lateral float is reduced, and the lateral float is a key for greatly improving the displacement sensitivity of the fishing group system. That is why the use of "thin and tough materials" is required for sidestream bleaching. And is one of the reasons that the current drainage float cannot meet the sensitivity requirement.

Therefore, the lateral flow float greatly improves the displacement sensitivity on the basis of meeting the visual float definition of the coarse tail float. The lateral flow tail may be referred to as a "fish-mouth signal amplifier".

The effect of this coarse tail is seen visually below with a special sized lateral flow float example while maintaining adequate sensitivity.

According to the float body characteristics of the actual use of the fishing hand, the diameters of the plug holes are designed to be 0.8mm, 1.0mm, 1.2mm and 1.5mm, so that the plug hole is applicable to the current commonly used float tail diameter and facilitates the plug replacement of the side-flow float. The diameter (outer diameter) of the float tail is divided into four specifications of 1.5mm, 2.0mm, 2.5mm and 3.0mm so as to meet the requirements of different fishing distances and different hooking purposes.

Through the trial of tens of thin and tough materials, medical film color ultra-printing paper can be selected as the hollow drift tail material (other materials which meet the thin and tough requirements can also be selected). Rolling into a tube shape, coating mesh holes to form a mesh-floating tail. Thin wall materials with different thicknesses are rolled into the eye-bleaching tail with different outer diameters, different equivalent tail-bleaching diameters are provided, and the fishing requirements are met in a wider range.

The parameters of the mesh and tail bleaching of specific side-stream bleaching are shown in the following table.

Note that: the equivalent diameter is the diameter of the solid float tail which is the same as the circular ring area of the cross section of the lateral flow float tail. The same hook has the same hook eye measured on both of them. I.e. with the same displacement sensitivity. The apparent ratio is the ratio of the diameter of the drift tail of the lateral flow drift to the equivalent diameter. Representative is the multiple of the visible diameter increase of the lateral flow float, while maintaining the sensitivity of the float at a finer tail diameter. The displacement sensitivity increase multiple is the same fish to suck the bait, and the ratio of the drift length of the sidestream drift to the drift decrease length of the solid drift with the same outer diameter (represented by the displacement sensitivity) is also equal to the square of the reciprocal of the ratio of the equivalent diameter of the sidestream drift to the diameter of the solid drift with the same outer diameter.

Even though the force of sucking the bait by the fish is not easily and precisely measured, it is determinable by the operator for a fish hook of a model and size that is matched to the particular size and variety of fish to be fished. In this way, the relationship between the force of sucking the bait by the fish and the buoyancy increment of the tail-floating characteristic is converted into the relationship between the fishhook and the tail-floating characteristic according to the object fish suitable for fishing. Specifically, a fishhook suitable for the object fish is pressed and floated on the tail of the selected float by about 2 meshes (the hook meshes are all available from 1 to 3 meshes). The color contrast of the two continuous meshes of the floating tail is about 2 meshes, so that the color contrast is high and the color is easy to distinguish. Therefore, the ratio state of the bottom or the suspension of the fishhook can be clearly judged from the change of the drift. Because the fishhook suitable for the sucking inlet of the object fish can express the mesh number easy to distinguish on the floating mesh, the object fish can express the mesh number easy to distinguish on the floating mesh when sucking the bait, namely the fishmouth is clear and distinguishable, which is beneficial to the fishing hand to catch the effective floating phase and improves the medium-sized fish rate. Therefore, the proper hook is to provide the fishing line system with basic displacement sensitivity.

Special case side drift models and matched common hook models are shown in the table below.

Note that: a designation of 0 indicates that the hook eye of this model on this model's lateral float measured is too small to match. The designation x indicates that the hook eye of this model on this model's lateral float measured is too large to match. The measured hook eye will also vary due to the different one-eye lengths of the different floats. It is generally recommended here to have a mesh length of 1 cm.

Thus, when the side-stream float of the present invention is used for fishing, a proper hook can be determined according to the size of the fishing species, and then the matched side-stream float model is selected according to the hook, so that the hook mesh measured on the selected side-stream float is about 2 meshes. Then the proper number of the fishing meshes is regulated and floated according to the specific gravity relation of the bait, and the fishing meshes are within 4 meshes or more (Kong Piaomu), so that the bait has an underwater state suitable for the fish mouth.

In addition, the external diameter and the wall thickness of the hollow floating tail can be adjusted to meet different hook mesh requirements, so that the fishing rod has wide fishing applicability.

Because the water inlet and outlet ports are arranged in the length of 1 mesh near the fishing mesh, the water flowing distance is extremely short, the water resistance is greatly reduced, and the sensitivity of the lateral flow drift is ensured. Meanwhile, the thickened lateral flow float outer diameter enables the user to see clearly even if the user angles far, so that the user can timely find and capture the signals of the fish mouth, and the middle fish rate is greatly improved. The used lateral flow drift tail is made of thin and tough materials, so that the equivalent drift tail diameter is greatly reduced, and thickening and protecting are feasible.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may be modified or some technical features may be replaced with others, which may not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (6)

1. The hollow row Shui Xingmu floating tail is characterized by comprising a floating tail body with a hollow inside, floating meshes are arranged on the outer wall of the floating tail body, interval meshes are arranged between two adjacent floating meshes, the colors of the interval meshes are different from those of the floating meshes, a plurality of water through holes communicated with the inside of the floating tail are arranged on the floating tail body, the water through holes are uniformly distributed in a staggered manner along the axial direction and the circumferential direction of the floating tail body, a floating tail connecting cap is connected at the bottom of the floating tail body, and the floating tail connecting cap and the floating tail body are detachably connected or integrally formed;

the floating tail connecting cap is provided with a plug hole for connecting the floating body, a silica gel layer is arranged in the plug hole, the floating tail connecting cap is a shell with a cavity inside, the cavity inside the floating tail connecting cap is filled with a filler, and the filler is made of the same material as the filler in the floating body;

the floating tail connecting cap comprises a transition sleeve integrally formed with the bottom of the floating tail body, a water-through support frame is arranged in the bottom of the sleeve, a water-through port is arranged on the water-through support frame, a connecting sleeve is coaxially fixed on the water-through support frame, and the outer diameter of the connecting sleeve is smaller than that of the transition sleeve.

2. The hollow row Shui Xingmu tail according to claim 1, wherein the inner wall of the tail body is coated with a hydrophobic membrane.

3. The hollow row Shui Xingmu float tail of claim 2, wherein said float tail body has a wall thickness of no more than 0.15 millimeters and said spacing target length is no more than half the float target length.

4. The hollow row Shui Xingmu drift tail of claim 2, wherein the water passage holes are formed by cutting out portions of the side walls on the spacer mesh, the area of the cut-out portions of the side walls being greater than half the surface area of the spacer mesh.

5. A sidestream buoy comprising a hollow row Shui Xingmu buoy tail as claimed in any one of claims 1 to 4, and further comprising a buoy body, wherein a transition buoy tail is arranged at the top of the buoy body, a buoy foot is arranged at the bottom of the buoy body, the transition buoy tail is inserted on a buoy tail connecting cap, and the outer diameter of the buoy tail body is larger than that of the transition buoy tail or the buoy foot.

6. A sidestream buoy comprising a hollow row Shui Xingmu buoy tail as claimed in any one of claims 1 to 4, and further comprising a buoy body, wherein a buoy foot is arranged at the bottom of the buoy body, the top of the buoy body is coaxially fixed on a buoy tail connecting cap, and the outer diameter of the buoy tail body is larger than that of the buoy foot.