JP5424703B2 - Fishing rod and fishing rod - Google Patents

Description

  The present invention relates to a fishing rod and a fishing rod having such a fishing rod.

  In general, the tip of a fishing rod is preferably configured so as to be easily bent and not to be damaged even if it is greatly bent when a fish is caught in order to improve fish reliability. Usually, it is known that the displacement of bending when a load is applied to a member such as a tip blade is represented by the sum of displacement due to bending moment and displacement due to shear force. As for the shearing force, if the shear modulus decreases, the shear displacement increases in inverse proportion. Here, looking at the shearing force when a load is applied to a member such as a spike, the shear stress in the central region increases, and if the shear modulus is increased to ensure a predetermined bending rigidity, the bending force It becomes a difficult point.

  However, it is preferable that the spikelet has such a characteristic that a certain degree of bending rigidity is ensured and has good flexibility and does not break even if it is greatly bent. For this reason, for example, as disclosed in Japanese Patent Application Laid-Open No. H10-228707, a tip knot that has a large curvature (allowing large deflection) by giving a role of reducing bending rigidity to shear displacement is disclosed. ing. Specifically, the spikelet is composed of a plurality of fiber reinforced resin layers in the radial direction, and the inner layer side reinforcing fiber ratio (ratio of reinforcing fibers to the matrix resin) is reduced, in other words, on the inner layer side. By disposing a fiber reinforced resin layer having a large amount of resin impregnation, the shear displacement in the central region is increased, and a sticky tip with good stickiness and flexibility is obtained.

JP-A-6-276897

  The above-mentioned well-known spikelet has a lower reinforcing fiber ratio on the inner layer side (a larger amount of resin impregnation) and a higher reinforcing fiber ratio on the outer layer side (a smaller amount of resin impregnation). Although it can be achieved, there is a problem that delamination is likely to occur between each layer when it is greatly bent, and damage or the like is likely to occur.

  The present invention has been made paying attention to the above-described problems, and an object of the present invention is to provide a fishing tip rod and a fishing rod that have good flexibility and are not easily damaged even when greatly bent.

  In order to achieve the above-described object, the present invention provides a solid fishing tip which is formed by arranging a plurality of reinforcing fiber bundles in which a plurality of reinforcing fibers oriented in the axial length direction are impregnated with a synthetic resin. In the fishing tip, when the cross section cut in a direction perpendicular to the longitudinal axis direction at any position is viewed, the resin impregnation amount in the center portion is more than the resin impregnation amount in the surface layer portion. The amount of resin impregnation is varied continuously along the radial direction.

  The above-described configuration is formed in a solid shape by arranging a plurality of bundles of reinforcing fibers obtained by impregnating a plurality of reinforcing fibers oriented in the axial length direction with a synthetic resin. In this case, the spikelet is impregnated with the synthetic resin while pulling out a plurality of reinforcing fiber bundles (a plurality of reinforcing fibers are arranged to form a bundle), and the reinforcing fiber bundles are gathered into a solid state. The synthetic resin can be cured by passing through the mold and further heated to finally obtain a solid structure.

  In such a process, for example, when pulling out each reinforcing fiber bundle and passing it through a mold, a plurality of reinforcing fiber bundles are arranged around the center, and a reinforcing fiber bundle having a large amount of resin impregnation is arranged in the central portion. Alternatively, when a cross section cut in a direction perpendicular to the longitudinal axis direction at any position by pulling a synthetic resin string at the center portion, the resin impregnation amount in the center portion is determined by the surface layer portion. It is possible to obtain a solid stylus that is larger than the resin impregnation amount.

  And, since the amount of resin impregnation in the central part is increased in this way, when the spikelet is greatly deflected, it is possible to increase the shear displacement in the center part, and the spikelet with excellent flexibility It becomes possible to do. Further, since the resin impregnation amount in the cross section at any one of the positions is in a state of continuously changing along the radial direction, a plurality of reinforcing fibers in the radial direction as described in the above-mentioned known literature. The delamination does not occur due to the presence of the layer, and it is possible to effectively prevent breakage when greatly deflected.

  Here, “continuous change” means that there is no portion in which the amount of resin impregnation changes drastically when the radial direction is seen in any cross section of the tip of the tip of the head (the boundary portion between different fiber reinforced resin layers). This means that the rate of change is 5% or less in the radial direction (if there is a boundary part, the rate of change in the amount of resin impregnation at that position is abrupt. To change).

  ADVANTAGE OF THE INVENTION According to this invention, the fishing rod which has favorable flexibility and is hard to be damaged even if it bends greatly, and a fishing rod which has such a fishing rod can be provided.

1 is an overall view of a fishing rod having a tip rod according to an embodiment of the present invention. The side view of the spikelet which concerns on one Embodiment of this invention. Sectional drawing of the reinforced fiber core which comprises the solid body of the spikelet of FIG. The schematic diagram of the cross section along the AA line (this position is arbitrary) of FIG. The graph which showed the measurement position of the content of the reinforced fiber in the cross-section of a spikelet, the measurement result, and the measurement result. Schematic which shows the dimensional relationship of the cross section of a spikelet. A photograph showing the cross-section of the solid body of the spikelet (photo showing the amount of resin impregnation in the circumferential direction not uniform). A photograph showing a cross-section of the solid body of a spikelet (photo showing a uniform amount of resin impregnation in the circumferential direction). Sectional drawing which shows another structure of the reinforced fiber core which comprises the solid body of the spikelet of FIG. Sectional drawing which shows another structure of the reinforced fiber core which comprises the solid body of the spikelet of FIG. The schematic diagram of the longitudinal cross-section in the arbitrary positions of the spikelet shown in FIG.

  Hereinafter, an embodiment of a fishing tip according to the present invention will be specifically described with reference to the accompanying drawings.

  FIG. 1 is a side view of a jointed fishing rod (for example, a rod) 1 with an outer guide according to the present invention. A base rod 10, a plurality of middle rods 12, a hot rod 18, and a tip rod 20 are swayed. It is joined to the formula. Of course, it may be a side-by-side or reverse side-by-side. Each of these cages is a fiber reinforced resin cage made of a synthetic resin such as an epoxy resin or a polyester resin and reinforced with a reinforcing fiber such as carbon fiber.

  In FIG. 2, a tip rod 20 is shown, and the tip rod 20 here has a hollow body 18 a of the tip holding rod 18 connected to a rear end portion 20 a of the solid body 20 </ b> A constituting the tip rod 20. Hereinafter, in the case where the ear tip is made of a solid product, as in this example, the solid body 20A reaches at the rear of the first outer guide g1 closest to the tip end of the tip tip having at least the top guide G20. Say things.

  Outer guides 12G, 18G, and 20G (top guides) are fixed to the tip portions of the hooks 12, 18, and 20, and the tip hook 20 has a floating type in the middle as shown in FIG. The first and second outer guides g1 and g2 are mounted. Accordingly, each bag can be stored in a swing-out manner. In the figure, reference numeral 22 is a reel, and reference numerals 12g and 18g are movable guides that are slidably provided on the middle rod 12 and the hot rod 18.

  Hereinafter, with reference to FIG. 2, a structural form of the solid body 20 </ b> A that constitutes the tip basket 20 will be described. The dimensional form of the solid body 20A is the difference between the diameter of the tip (0.7 mm) and the diameter of the base of the front thin taper portion (1.9 mm) excluding the connection rear end portion 20a (1.9 mm). ) Is 0.0024. Further, the mounting position of the first outer guide g1 that is closest to the top guide 20G is a position 105 mm behind the tip 90 of the scissors tip 20. The second outer guide g2 is also provided in the area of the solid body 20A.

The solid body 20A is formed of a so-called solid body in which all reinforcing fibers (reinforcing fibers) are oriented in the axial direction. In this case, a plurality of reinforcing fiber bundles made up of a large number of reinforcing fibers are aggregated, for example, a fiber reinforced resin tip with a polyester resin as a matrix. Carbon fibers and the like are mainly used as the reinforcing fibers, and those having a tensile elastic modulus in the range of 10,000 kgf / mm ² (98000 N / mm ² ) to 40000 kgf / mm ² (392000 N / mm ² ) are used. Further, the amount of the synthetic resin impregnated in the reinforcing fiber bundle may be within the range of 40 to 70% by weight in a state where the amount of resin impregnation at the center is large when the cross section is finally seen.

  In this case, the impregnation amount of the synthetic resin can be specified by the area ratio of the exposed resin part and the fiber part when looking at the cross section at any position of the tip of the tip that became the molded product It is. That is, it is possible to specify the resin impregnation amount (fiber content; VF) by comparing the areas of the synthetic resin portion and the reinforcing fiber portion that appear in the unit area with the cross section cut. Moreover, about each fiber diameter which comprises each reinforcing fiber bundle, it is about 6-10 micrometers. Furthermore, each reinforcing fiber bundle is configured by, for example, bundling 12,000 reinforcing fibers, and a plurality of such fiber bundles are assembled to form the solid body 20A.

  As described above, in the present invention, when the cross section is viewed at any position, the solid body is formed so that the resin impregnation amount in the central portion is larger than that in the surface layer portion. Hereinafter, an example of a process for manufacturing such a solid body will be described.

  The solid body 20A is manufactured by, for example, a pultrusion method. That is, the reinforcing fiber bundle (fiber core body) 80 constituting the solid body 20A may have four (of course, more than that, three) as shown in FIG. (Better) reinforcing fiber bundles 50 are arranged, and one reinforcing fiber bundle 51 having a larger resin impregnation amount than the reinforcing fiber bundles 50 arranged around the center is arranged at the center, and these are assembled together. A solid entity is formed.

  Specifically, the reinforcing fiber bundles 50 and 51 drawn out from the bobbin or the like are passed through an impregnation tank in which the synthetic resin is stored and impregnated with a sufficient amount of the synthetic resin (the reinforcing fiber bundle 51 located in the center is Is impregnated with a larger amount of resin than the reinforcing fiber bundle 50), pulled out through a guide arranged on a concentric circle, drawn into the mold, and squeezed into the mold to squeeze the resin and bring the reinforcing fiber bundles into close contact. At this time, by the heating process, the reinforcing fiber bundles 50 and 51 are integrated by the resin flowing out in a close contact state to form one solid body. And what was formed in that way is cut | disconnected to desired length, and taper processing (grinding stone grinding | polishing process) is carried out, and solid body (point tip) 20A is formed.

  Thereby, since there are not a plurality of fiber reinforced resin layers as in the known technique in the radial direction in the cross section of the tip, a tip tip configuration in which delamination does not occur is obtained. Moreover, about the amount of synthetic resin impregnated, the central portion is in a resin-rich state by arranging the reinforcing fiber bundle 51 impregnated with a large amount of synthetic resin at the center, so that from the central portion toward the surface layer portion. Thus, a configuration in which the resin impregnation amount “continuously changes” can be obtained. That is, the solid body obtained by such a process does not have a portion where the resin impregnation amount changes extremely because a plurality of layers are not formed when the radial direction is viewed in any cross section, and the diameter The change rate of the resin impregnation amount over the direction (here, the change rate when the resin impregnation amount per unit area adjacent at an arbitrary position along the radial direction is compared) is 5% or less. A state comes to be obtained.

  Here, with reference to FIGS. 4 to 6, the amount of impregnation of the synthetic resin described above will be specifically described.

  FIG. 4 is a schematic diagram of a cross section taken along line AA in FIG. 2 (this position is arbitrary). As shown in this figure, the tip 20 is in a state in which the resin impregnation amount in the central portion C is larger than the resin impregnation amount in the surface layer portion S by using the manufacturing process described above. The amount of resin impregnation can be specified by the area ratio of the synthetic resin and the reinforcing fiber per unit area, and the amount of the synthetic resin impregnated in the region of the central portion C specified in this way can be specified in the same way. As long as it is larger than the amount of the synthetic resin impregnated on the surface layer portion S side (the region of the central portion C here is within the range of D / 5 shown in FIG. 6, and the region on the surface layer portion S side) Is within the range of D / 10 shown in FIG.

  Specifically, in the manufacturing process described above, as shown in FIG. 5, when the diameter of the cross-section of the tip is D (in this position, D is 2.04 mm), the diameter direction is arbitrary. When the content of reinforcing fiber VF (opposite value of impregnation amount of synthetic resin) is measured at the position, the VF in the central portion is the smallest (the amount of impregnation of the synthetic resin is the largest), and the larger the displacement point as it moves to the surface layer side. A configuration in which VF continuously increases without being generated is obtained. That is, when the synthetic resin impregnation amount is measured at an arbitrary position in the radial direction, and the measurement position is plotted and graphed (drawing an approximate curve), there is no portion that changes extremely as shown in the figure (large A smooth curve line (no inflection point) is obtained.

  Thereby, even if it bends greatly, even if it bends greatly, delamination does not arise in the inside, but it will be able to obtain the tip heel which does not produce damage etc. easily.

  In the above-described configuration, as shown in FIG. 6, when the diameter of the cross-section of the tip collar at an arbitrary position is D, the amount of resin impregnation within the range of D / 5 centered on the central portion C is from the surface. It is preferable that the amount of resin impregnation within the range of D / 10 is 10% or more.

  By setting such a ratio of the resin impregnation amount, shear deformation in the center part is sufficiently allowed, and it is possible to obtain a harpoon that is more flexible and less likely to be damaged even if greatly bent. become.

  Also, when molding the tip of the above-described configuration, the amount of resin impregnation varies in the circumferential direction at any position in the radial direction when looking at the cross section of the solid body to be finally molded. It is preferable that it is in the state which is not. That is, as described above, it is preferable that the resin impregnation amount does not change greatly even in a state along the circumferential direction as well as in the radial direction (a configuration in which there is no boundary portion extending in the radial direction). .

  As a factor that the amount of the synthetic resin impregnation changes in the circumferential direction, as shown in FIG. 3, when the plurality of reinforcing fiber bundles 50 and 51 are pulled out, the reinforcing fiber bundles are simply gathered and pulled out as they are. It is presumed that the reinforcing fiber bundles are generated by the resin remaining in the boundary portion without sticking to each other. Thus, if the reinforcing fiber bundles do not sufficiently adhere to each other, the synthetic resin tends to accumulate at the boundary portion, and as shown in the photograph of FIG. 7, the portion where the synthetic resin increases is indefinite shape (indefinite in the radial direction). Shape).

  For this reason, for example, when the reinforcing fibers are assembled and pulled out, the reinforcing fiber bundles can be in close contact with each other, and the reinforcing fiber bundles are preliminarily formed so that the resin pool does not occur at the boundary portion. When these are assembled and pulled out, as shown in the photograph of FIG. 8, a configuration in which the resin impregnation amount does not change greatly when viewed in the circumferential direction can be obtained. In FIGS. 7 and 8, the white portions are the exposed reinforcing fibers (cross sections of the cut reinforcing fibers) when viewed as a cross section, and the black portions of the photographs are synthetic resin (reinforced). Synthetic resin part where no fiber is present).

  In this case, the wrinkles to be formed in advance are appropriately deformed, but if the wrinkles are too large or too small, the amount of resin impregnation changes significantly, so that 5-10 turns per meter in the longitudinal direction. By forming a twist and passing through a heating furnace and curing by heating, it is possible to suppress a change in the resin impregnation amount in the circumferential direction within a range of ± 5%. Thus, when the circumferential direction is viewed at a certain radial position, the resin impregnation amount is preferably changed within a range of ± 5%.

  As a result, even when viewed in the circumferential direction, there is no portion where the amount of impregnation of the synthetic resin changes greatly (such a portion is a portion that is easily peeled off), so that the tip is not easily damaged even if it is greatly bent. You can get candy.

  In the above-described configuration, the reinforcing fibers used in the reinforcing fiber bundles 50 and 51 have the same characteristics such as the diameter and the elastic modulus, so that even if they are largely bent as described above, they are damaged. It is possible to further improve the operational effect that is difficult to occur.

  Alternatively, when the characteristics as a fishing rod (head rod) are considered, the elastic modulus of the reinforcing fiber on the surface layer side may be higher than the elastic modulus of the reinforcing fiber in the center. Specifically, as shown in FIG. 6, when the diameter is D in the cross-section of the tip, the elastic modulus of the reinforcing fiber within the range of D / 10 from the surface is D / 5 from the center. By making the elastic modulus higher than the elastic modulus of the reinforcing fiber within the range, it is possible to increase the elasticity of the outer layer side where the strain increases, thereby ensuring the desired rigidity while enabling large deflection It becomes possible to do.

  As shown in FIG. 3, as a process for obtaining the above-mentioned head portion having a large amount of resin impregnation at the center, as shown in FIG. Although a plurality of reinforcing fiber bundles 50 having a small amount are arranged, the present invention is not limited to such a configuration. For example, as shown in FIG. 9, a synthetic resin string 53 may be arranged and pulled out at the center. As a result, it is possible to obtain a spike with a higher resin impregnation amount in the central part than in the surface layer part. Alternatively, as shown in FIG. 10, four of the above-described plurality of reinforcing fiber bundles 50 are assembled, and, for example, the reinforcing fiber bundle 50 is pulled out from the mold while the synthetic resin is injected into the central portion, or pulled out into the mold. By using a process such as squeezing the resin in the surface layer by adjusting the diameter of the die at the time, it is possible to obtain a spike with a higher impregnation in the center than in the surface layer. In addition, in such a process, it is also possible to obtain a configuration in which the resin impregnation amount does not change greatly when viewed in the circumferential direction by twisting the reinforcing fiber bundles as a whole.

  Moreover, in the above-described configuration, the cross section of the solid tip is considered, but the longitudinal fiber structure at any position is further configured by forming the reinforcing fiber bundle so as to have the following structure. A structure that is excellent in flexibility and is less likely to be damaged even if it is greatly bent is obtained.

  That is, when looking at the longitudinal cross-section cut along the longitudinal axis direction at any position, the reinforced fiber exposed in the longitudinal cross-section, the exposed length along the longitudinal axis direction of the cut longitudinal cross-section It is preferable to configure such that those having a length shorter than the unit length of 1 mm in the longitudinal axis direction and different exposure lengths are mixed.

  Specifically, when cut along the longitudinal axis direction at any position along the longitudinal axis direction of the solid body 20A (the tip rod 20), the reinforcing fibers are arranged as schematically shown in FIG. (In this case, in order to make the state of the reinforcing fiber easy to understand, the amount of the reinforcing fiber that is exposed is shown small). Such a longitudinal section is always seen at any arbitrary position (axial center position in the longitudinal direction or any radial position eccentric from the axial position) along the longitudinal axis direction of the tip heel 20. Reference numerals 60, 62, 64, 66,... Are exposed (cut) exposed portions of the reinforcing fibers exposed in the longitudinal section.

  The fibers exposed in this longitudinal section are all (or at least 80% or more), and the longitudinal axis direction of the longitudinal section in which the exposed lengths l1, l2, l3, l4... Along the longitudinal axis direction are cut. The unit length L is shorter than 1.0 mm. That is, although the reinforcing fibers constituting the reinforcing fiber bundles 50 and 51 described above extend over the entire length of the spikelet, the reinforcing fibers exposed in the cut longitudinal section are exposed along the longitudinal axis direction. The lengths l1, l2, l3, l4... Are shorter than the unit length L of 1 mm in the longitudinal axis direction of the cut longitudinal section.

  This is because the portion where the fiber is shortened in the longitudinal cross section, that is, the unexposed portion of the fiber exposed in the longitudinal cross section (the portion not exposed in the cross section) extends along the longitudinal axis direction of the tip rod 20. It extends at an angle in an arbitrary direction with respect to the longitudinal axis direction (diverted from the longitudinal axis direction), and is therefore hidden by the synthetic resin (or a longitudinal section along the longitudinal axis direction). Does not appear on the surface).

  Therefore, the actual length of the reinforcing fiber itself exposed in the longitudinal section (the length in the longitudinal section) is the length L in the longitudinal axis direction of the longitudinal section by the amount inclined with respect to the longitudinal axis direction. As a result, the total length of the fiber is also longer than the total length of the tip rod 20.

  Further, in this longitudinal section, the reinforcing fibers have different exposure lengths (the reinforcement fibers exposed in the longitudinal section have different inclination angles with respect to the longitudinal axis direction (l1, l2, l3, l4,.・ ・)) Are mixed. In this way, as the form with different exposed lengths, the same reinforcing fiber crosses the longitudinal section several times (meanders), so that a plurality of portions of the reinforcing fiber are exposed in the longitudinal section and the exposed length. May be different, or may have different exposure lengths between different reinforcing fibers. In addition, the reinforcing fibers exposed in the longitudinal section are mixed with those having different exposure directions (directions with respect to the longitudinal axis direction).

  Furthermore, 50% or more of the entire fiber exposed in the cut longitudinal section is inclined by 1 ° to 20 ° in an arbitrary direction with respect to the longitudinal axis direction of the tip rod 20. That is, in the illustrated configuration example, for example, an exposed portion 60 (a portion having an exposed length of 11) of the fiber that is inclined by 20 ° with respect to the longitudinal axis direction of the tip rod 20, and a longitudinal axis direction of the tip rod 20 A fiber exposed portion 62 (exposed length l2) inclined by 10 ° with respect to the fiber, an exposed portion 64 (exposed length l3 portion) of fiber inclined by 6 ° with respect to the longitudinal axis direction of the tip tip 20, and a tip tip The exposed portion 66 (the exposed length 14 portion) of the fiber inclined by 1 ° with respect to the longitudinal direction of 20 is illustrated as an example, but the reinforcing fiber having such an inclination angle of 1 ° to 20 °. However, it is preferable if it occupies 50% or more of the entire fiber exposed in the longitudinal section.

  Further, the ratio of the reinforcing fibers having an exposed length of 0.5 mm or less is preferably larger than the ratio of the fibers having an exposed length longer than 0.5 mm. If such a cross-sectional form is formed, since the ratio of fibers having a large inclination angle increases, it can be prevented from being damaged even if it is further bent. Specifically, in the longitudinal cross section, the ratio of the exposed length of the entire fiber having a length of 0.05 mm to 0.4 mm is 20% or more. Preferably, the ratio of the exposed length of the entire fiber having a length of 0.05 mm to 0.3 mm is 30% or more. If it has such a longitudinal cross section, the fiber with a large inclination angle will increase, and the damage prevention effect by large deflection will increase.

  As means for obtaining the reinforcing fiber arrangement as described above, for example, the reinforcing fiber bundles 50 and 51 can be twisted as a whole. Alternatively, the reinforcing fibers in the reinforcing fiber bundle can be obtained in the form of waving along the longitudinal axis direction (waved form). Such a corrugated form of the reinforcing fiber is formed by, for example, passing a fiber core body 80 impregnated with a resin and having a plurality of reinforcing fiber bundles 50 and 51 aligned in the axial direction through a guide disposed on a concentric circle. By pulling out the reinforcing fiber bundle 51 located at the center more strongly than the other reinforcing fiber bundles 50, the surrounding reinforcing fiber bundle can be obtained in a wave shape. In addition, each reinforcing fiber bundle may be formed by twisting a number of reinforcing fibers constituting the reinforcing fiber bundle in a straight line in the axial direction or by twisting (each fiber bundle itself has a twist). Also) good.

  As described above, the actual length of the reinforcing fiber itself exposed in the longitudinal section (the length in the longitudinal section) is inclined with respect to the longitudinal axis direction by the lengthwise direction of the longitudinal section. As a result, the total length of the reinforcing fiber is also longer than the total length of the tip. That is, since the length of the reinforcing fiber is secured in advance by the amount of elongation of the reinforcing fiber in the axial direction when the tip is bent, the tip is greatly deflected by the secured amount. Accordingly, even if a large amount of bending occurs and local bending occurs, it is possible to obtain a configuration that is not easily damaged.

  Further, in the above-described configuration, the reinforcing fibers exposed in the longitudinal section are mixed with those having different exposed lengths, so that the reinforcing fibers having a long exposed length due to bending of the tip of the tip (a reinforcing fiber having a small breaking elongation) Even if the fiber breaks first, the reinforcing fiber having a short exposed length (the reinforcing fiber having a high elongation at break) remains without breaking, and as a result, the above-described effects can be further promoted.

  As mentioned above, although the tip cocoon described as the embodiment of the present invention is formed in a solid shape over the entire longitudinal direction, a configuration in which the solid portion and the hollow portion are combined may be used. In that case, the reinforcing fiber extends at least over the entire length of the solid portion, and it is sufficient that the above-described structure is obtained at least in the solid portion.

1 Jointed fishing rod with outside guide (fishing rod)
20 Earpiece 50, 51 Reinforced fiber bundle 53 Synthetic resin string

Claims (7)

A solid fishing tip that is formed by arranging a plurality of reinforcing fiber bundles in which a plurality of reinforcing fibers oriented in the axial length direction are impregnated with synthetic resin,
When the cross-section cut in a direction perpendicular to the longitudinal axis direction at any position, the fishing rod is larger in the resin impregnation amount in the central portion than the resin impregnation amount in the surface layer portion and has a diameter. A fishing tip rod characterized by continuously changing the amount of resin impregnation along the direction.   In the cross-section of the fishing tip, if the diameter is D, the resin impregnation amount within the range of D / 5 centered on the center is the resin impregnation amount within the range of D / 10 from the surface. The tip of a fishing rod according to claim 1, characterized in that the amount is 10% or more. In the cross section of the fishing tip, when the diameter is D, the elastic modulus of the reinforcing fiber within the range of D / 10 from the surface is that of the reinforcing fiber within the range of D / 5 centered on the center . The tip of a fishing rod according to claim 1 or 2, wherein the tip is higher than an elastic modulus.   The tip of a fishing rod according to claim 1, wherein reinforcing fibers having the same characteristics are used from the center to the surface layer. 5. The change in the amount of resin impregnation along the circumferential direction at any position in the radial direction in the cross section of the fishing tip is within a range of ± 5%. The tip of a fishing rod according to any one of the above.   When the fishing rod is seen in a longitudinal section cut along the longitudinal axis direction at any position, the reinforcing fiber exposed in the longitudinal section has a longitudinal section where the exposed length along the longitudinal axis direction is cut. 6. A fishing tip rod according to any one of claims 1 to 5, wherein those having a different exposure length than a unit length of 1 mm in the longitudinal axis direction of the surface are mixed.   A fishing rod having the tip for fishing according to any one of claims 1 to 6.