JP2010154783A - Line guide, and method for producing guide ring - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a line guide which is small, lightweight, and hardly causes peeling, abrasion, or the like on the surface portion. <P>SOLUTION: The guide ring of the line guide is made of a titanium-based material and in which a carbon-doped titanium oxide layer is formed on the surface of a body member 2 having a line guide, The carbon-doped titanium oxide layer 2A contains a titanium-carbon bond state and is formed to have a hardness higher than a titanium-based material, and the surface has unevenness treated to be polished in a polishing step. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fishing line guide to be mounted on a fishing article such as a fishing rod or a reel, and a method for manufacturing a guide ring constituting the fishing line guide.

Conventionally, ceramics such as silicon carbide (SIC) are used for fishing line guides attached to fishing rods called outer guide systems, and parts that are attached to such fishing line guides and through which fishing lines are inserted. There is. Since such ceramics have high hardness and excellent wear resistance, they are used in the portion (guide ring) of the fishing line guide where the fishing line comes into contact. Further, for example, Patent Literature 1 discloses a fishing gear applicable as a guide ring for a fishing line guide. In the fishing gear disclosed in Patent Document 1, the base material is made of ceramics, and a coating layer of metal or the like is formed on the surface.
Japanese Patent Laid-Open No. 1-265841

  Since the ceramics described above are vulnerable to impacts, it is necessary to form a thick wall, which has the disadvantage of being heavy and large. For this reason, considering the attachment of ceramic parts to the fishing line contact portion of the tip guide, it is necessary to secure a certain thickness, so the weight of the tip guide becomes heavier and larger. Therefore, a fishing rod that senses a delicate attack, particularly a pointed rod, is not preferable.

  Further, as disclosed in Patent Document 1 described above, when a metal coating layer is formed on the surface of ceramics, there is a problem that the metal coating layer peels off and damages the fishing line when corrosion or wear occurs. .

  The present invention has been made on the basis of the above-described problems, and is a fishing line guide that is small and light in weight and is less likely to be peeled off or worn on the surface portion, and manufacture of a guide ring constituting such a fishing line guide. It aims to provide a method.

  In order to achieve the above-described object, a fishing line guide according to the present invention is composed of a titanium-based material, a guide ring in which a carbon-doped titanium oxide layer is formed on the surface of a main body member having a fishing line guide portion, and the guide ring includes: A fishing line guide comprising a frame to be attached, wherein the carbon-doped titanium oxide layer includes a state in which titanium and carbon are bonded, and is formed to have a hardness higher than that of the titanium-based material. Is characterized by being processed in a state in which the irregularities are polished by the polishing step.

  The guide ring of the fishing line guide having the above-described structure is made of a titanium-based material, and the surface of the main body member having the fishing line guide portion is modified to a carbon-doped titanium oxide layer over a predetermined depth (titanium and carbon Is included). That is, a titanium-based material is used as a main body member of a fishing line guide ring, not a member such as ceramics. By simply modifying the surface itself, the surface hardness is increased and the wear resistance is increased. As a result, the weight and size can be reduced. In particular, since the surface is processed in a state in which the unevenness is polished by the polishing process, the fishing line can smoothly slide and the wear resistance can be improved at the portion where the fishing line contacts. .

  The guide ring of the fishing line guide as described above is made of, for example, a titanium-based material, a first polishing process for polishing a plate-like main body member on which a fishing line guide portion is formed, and a carbon-doped oxidation on the surface of the main body member It is possible to manufacture by a step of forming a titanium layer and a second polishing step of polishing the surface irregularities generated when the carbon-doped titanium oxide layer is formed flat.

  In this case, when configuring the plate-shaped main body member on which the fishing line guide portion is formed, the portion where the fishing line contacts can be made smooth in advance by performing the first polishing step. A carbon-doped titanium oxide layer is formed in such a smooth state. Of course, as a fishing line guide, for example, as long as it is a part where the fishing line does not contact or a part attached to a fishing rod, such a configuration that does not perform such a first polishing step may be used. And by performing said 2nd grinding | polishing process, since the unevenness | corrugation in the surface is grind | polished and flattened, peeling of the surface is prevented and abrasion resistance improves, so that an external appearance can also be aimed at. Become.

  According to the present invention, it is possible to obtain a fishing line guide that is reduced in size and weight and is less likely to be peeled off or worn on the surface portion.

Hereinafter, an embodiment of the present invention will be specifically described.
In describing the embodiment of the present invention, first, a method for modifying the surface by forming a carbon-doped titanium oxide layer on the surface of the body member constituting the guide ring of the fishing line guide will be described. A specific fishing line guide manufactured by such a method will be described.

  1 to 4 show a state in which the surface of the main body member constituting the guide ring of the fishing line guide is modified, FIG. 1 is a schematic side view, and FIG. 2 is a state in which the fishing line is in sliding contact. FIG. 3 is an enlarged cross-sectional view schematically showing a state in which a carbon-doped titanium oxide layer is formed, and FIG. 4 is a view showing a predetermined polishing process in the state shown in FIG. It is an expanded sectional view showing the applied state typically.

  The main body member 1 constituting the guide ring of the fishing line guide has a titanium-based material, that is, titanium (pure Ti), various known titanium alloys (for example, β titanium (Ti-15v-3Cr-3Sn-3Al), , Α-β titanium (Ti-6Al-4V) or the like is used. In addition, about the main body member 1, what is necessary is just to use titanium or a titanium alloy for the required part, and it is possible to use it combining the metal material and resin material etc. which are different from titanium and a titanium alloy about another part. It is.

  Then, as will be described later, the carbon-doped titanium oxide layer 2A is formed on the titanium or titanium alloy surface 2 such as a portion that guides the fishing line or contacts the fishing line by the following procedure.

  First, the titanium-based material described above is processed into a predetermined shape (for example, a plate-like shape in which a fishing line guide portion through which a fishing line is inserted) as a guide ring of a fishing line guide. In this case, the processed guide ring is polished to a smooth state before forming the carbon-doped titanium oxide layer 2A by, for example, a polishing process (first polishing process) such as barrel polishing or chemical polishing. It is preferable to keep it. That is, by performing such a first polishing step, the surface of the formed carbon-doped titanium oxide layer 2A can be as smooth as possible. In addition, depending on the site | part to be used, it is not necessary to give such a 1st grinding | polishing process.

  Next, a carbon-doped titanium oxide layer 2A is formed on the surface 2 by a predetermined method. Specifically, for example, the above-described main body member 1 is held in the combustion chamber, and a high-temperature heat treatment is performed by directly applying a combustion flame of a gas containing hydrocarbon as a main component, or the main body member 1 is By a high temperature heat treatment in a combustion gas atmosphere of a gas containing hydrocarbon as a main component, or by a high temperature heat treatment on the surface of the main body member 1 in a gas atmosphere containing a hydrocarbon as a main component. The carbon-doped titanium oxide layer 2 </ b> A can be formed on the surface 2 of the main body member 1.

  The carbon-doped titanium oxide layer 2A formed in this way includes a state where titanium and carbon constituting the main body member 1 are bonded (Ti-C bond), that is, a bonded state in which the hardness is higher than that of the main body member. In addition, by doping carbon, the surface of the titanium-based metal is modified and the hardness can be improved.

  In this case, the carbon-doped titanium oxide layer 2A formed on the surface has a depth (thickness from the surface) of 0.1 μm or more or 0.5 μm or more, preferably 0.5 μm to 20 μm, more preferably It is preferably formed so as to be in the range of 1.0 to 20 μm.

  In order to obtain the reformed state with the above-described thickness, the gas containing hydrocarbon as a main component only needs to contain at least 50% by volume of hydrocarbon, and appropriately mixed with air, hydrogen, oxygen, and the like. Just do it. In other words, the carbon-doped titanium oxide layer 2A to be formed exhibits sufficient performance as a fishing line guide if the carbon content at the atomic level is 0.5 at% to 20 at%, preferably 1 at% to 15 at%. It becomes possible.

  Moreover, the above-described high-temperature heat treatment is such that the carbon-doped titanium oxide layer 2A having the above-described depth is formed on the surface 2 of the main body member 1, preferably the surface temperature of the main body member 1 is 900 ° C to 1500 ° C. Heat treatment may be performed so that the temperature is preferably 1000 ° C to 1200 ° C. That is, when the surface temperature is lower than 900 ° C., the thickness of the carbon-doped titanium oxide layer 2A tends to be thin, and when it is higher than 1500 ° C., the thin film tends to be peeled off from the member main body surface during cooling.

  Also, the heat treatment time is set to a time that does not cause the surface to peel off during cooling, and has a correlation with the heating temperature and is adjusted to an optimum condition, but it should be set to 600 seconds or less. preferable. That is, when the heat treatment is performed for more than 600 seconds, a tendency that the thin film is peeled off from the surface of the member main body appears at the time of cooling.

  The carbon-doped titanium oxide layer 2 </ b> A is formed on the surface 2 of the main body member 1 by the process described above. In such a carbon-doped titanium oxide layer 2A, since carbon is doped from the surface side and heat treatment is performed, the ratio of the state in which carbon and titanium are bonded (the ratio of Ti-C bonds) is relatively relatively low on the surface side. There are many, and the hardness on the surface side where the fishing line slides is improved as compared with the titanium-based material constituting the main body member, and the wear resistance is excellent.

  When the surface of the carbon-doped titanium oxide layer 2A is enlarged, as shown in FIG. 3, asperities 2a are formed and recesses (micro-recesses) 2b are formed in places. In this case, it is considered that the unevenness 2a and the recess 2b are caused by titanium atoms that could not be bonded to carbon or impurities other than titanium atoms. In particular, the concave portion 2b may be caused by a large concave portion that could not be polished in the first polishing step described above, and may be caused by the concave portion remaining as it is after the carbon-doped titanium oxide layer 2A is formed. Guessed.

  And such unevenness | corrugation 2a and the recessed part 2b become a frictional resistance when a fishing line slides, or a factor which peels a surface part (factor which peels the particle | grains of a surface part). Moreover, about the recessed part 2b, the boundary part (edge part) 2c with the surface (surface used as the unevenness | corrugation) is in a non-uniform | heterogenous state (pointed, stepped, uneven | corrugated, etc.) ) May damage the sliding fishing line or cause frictional resistance.

  For this reason, after forming the above-described carbon-doped titanium oxide layer 2A, a polishing step (second polishing step) for polishing the surface is further performed. In this case, in the second polishing step, it is preferable to polish the surface of the SIC guide ring used in the conventional fishing line guide to such a degree that the surface is glossy and smooth. Specifically, if the numerical value relating to the surface roughness (JIS B0601-2001) is about Ra 0.01 to 1.0, the unevenness is polished and a smooth surface can be obtained as follows. Become.

  In the second polishing step, barrel polishing can be used as in the above-described first polishing step. Such a barrel polishing process is performed by using, for example, a rotating barrel or a centrifugal barrel.

  Specifically, the barrel polishing step is performed in a state where the carbon-doped titanium oxide layer 2A is maintained, and the surface is smooth and has a higher surface hardness (a state in which carbon and titanium are bonded). (The ratio of Ti—C bonds) is relatively high on the surface side in the thickness direction of the layer).

  As shown in FIG. 4, the surface after the barrel polishing process is such that the unevenness 2 a existing in FIG. 3 is polished and the surface 2 a ′ is smooth, and is present in FIG. 3. Although the recessed portion 2b was completely polished and never disappeared, the edge portion 2c 'is polished in a curved shape (R shape). Thus, as schematically shown in FIG. 2, even when the fishing line S is in sliding contact with the surface, the unevenness 2a is polished and smoothed as described above, and the edge portion 2c ' Since it is polished in a curved shape (R shape), it is possible to smoothly guide the fishing line S without damaging it and to obtain a wear-resistant surface state. The concave portion 2b may be generated by partly peeling off due to non-uniformity of particles in the second polishing step described above, but the edge portion 2c ′ is curved by the polishing step. Polished.

  Moreover, it becomes possible to make surface hardness higher by performing the above-mentioned 2nd grinding | polishing process. This is because by polishing the surface region, the portion where carbon and titanium are not bonded (incompletely bonded portion and easy to be polished) is polished, so that a large proportion of Ti—C bonds exist on the surface side. It is presumed that the hardness has been improved as a result. In this case, the final surface hardness is preferably polished to a Vickers hardness (HV) higher than 1000. In addition, since the wear resistance can be improved by increasing the hardness, it is preferable that the polishing process is performed so that the fishing line is 1200 or more, more preferably 1500 or more, particularly in a portion where the fishing line is in sliding contact.

  Moreover, it is preferable to fill the recess 2b on the surface with a material having water repellency after the second polishing step. For example, it is possible to fill the recess 2b with a material having water repellency by applying a fluororesin or a fluorine paint and then polishing the surface. Or you may make it fill the recessed part 2b with a water-repellent material by spraying and painting the fluororesin which increased the ratio of the solvent. In such a configuration, since the portion that is originally a recess maintains water repellency, adhesion of moisture is prevented, and the slidability of the fishing line can be further improved.

  Alternatively, after the second polishing step described above, a grinding process may be performed on a desired position. The grinding process can be performed, for example, by a technique such as sand blasting or sanding. By performing such a grinding process, the carbon-doped titanium oxide layer 2A is thinned or shaved until the titanium-based material is exposed, The surface hardness can be lowered and the body member can have a structure (a structure with stickiness) in which the portion is not easily broken or damaged.

  The titanium-based material whose surface is modified by the above-described process has the following characteristics, and can improve the function as a guide ring of the fishing line guide.

  When the same fishing line sliding test was performed on the same shape SIC ring and a titanium-based material ring having a modified surface and the state of the heat pool was measured, the latter fishing line guide surface was The temperature was 1 degree or more lower than that, and it was confirmed that the structure was difficult to accumulate heat. This makes it possible to make the fishing line difficult to break at the fishing line insertion portion of the fishing line guide that has good heat dissipation and in particular the fishing line contacts with strong resistance.

  In addition, the modified surface had a good catalytic action (photocatalytic action) when irradiated with light as compared with the SIC member. Thereby, improvement of deodorization, bacteria prevention, antifouling, etc. comes to be aimed at.

Next, a first embodiment of a fishing line guide having a guide ring whose surface is modified as described above will be specifically described with reference to FIG.
As shown in the drawing, the fishing line guide 5 of this embodiment includes a ring-shaped guide ring 26 made of a titanium-based material and having a main body member having a fishing line guide portion 21 through which the fishing line is inserted. The frame 20 has a separate structure, and a cylindrical portion 10 in which an opening 11 to be fitted into a fishing rod is formed. A guide ring 26 is attached to an opening 20 a formed in the frame 20.

  The cylindrical portion 10 is integrally formed of a material such as synthetic resin, for example, and when inserted into the fishing rod R, the outer shape (on the tip side) of the fishing line S is easily removed in the direction of the arrow as shown in FIG. The shape of the base rod side is formed so that a step difference from the outer surface of the fishing rod R does not occur. Further, the cylindrical portion 10 is formed with a rotation-preventing protrusion 12 on the tip side to which the fixing portion 22 of the frame 20 is press-fitted and fixed.

  The frame 20 has a plate-like shape and is formed of, for example, a titanium-based material, and a fixing portion (opening) 22 that is press-fitted and fixed to the rotation preventing portion 12 of the cylindrical portion 10 is formed on the lower side. Has been.

  Further, the frame 20 has a curved protrusion 25 formed radially outward of the fixing portion 22, and when the fixing portion 22 is press-fitted and fixed to the anti-rotation protrusion 12 of the cylinder portion 10, It protrudes in a curved shape from the outer surface of the part, thereby making it difficult to catch the fishing line.

  The above-described guide ring 26 is punched and then subjected to the first polishing step described above, and then a carbon-doped titanium oxide layer is formed on the entire surface. And after forming a carbon dope titanium oxide layer, the above-mentioned barrel grinding | polishing (2nd grinding | polishing process) is given, and the unevenness | corrugation which generate | occur | produced on the surface is grind | polished.

  The inner peripheral surface (fishing guide surface) 21a of the fishing line guide 21 formed on the guide ring 26 is a part on which the fishing line fed out from the reel slides, and the surface of this part is carbon-doped through the manufacturing process described above. The titanium oxide layer 2A is formed (see FIGS. 1, 2, and 4). By forming the carbon-doped titanium oxide layer 2A on the inner peripheral surface (fishing line guide surface) 21a, as described above, the hardness can be improved and the wear resistance can be improved.

  As a result, the fishing line guide according to the present embodiment can be reduced in size and weight as compared with the conventional one, and can obtain a configuration that does not damage the fishing line that is inserted. Therefore, when considering the fishing line guide attached to the tip, the hardness and wear resistance can be improved and the weight can be reduced, so that it is possible to obtain a tip that has excellent fish confidence. Further, the guide ring 26 is formed with a carbon-doped titanium oxide layer having wear resistance and excellent smoothness over the entire surface portion thereof, so that it is possible to provide a fishing line guide that is less likely to be entangled. It becomes.

  Further, in the guide ring 26 of the present embodiment, since the polishing process is performed both before and after the carbon-doped titanium oxide layer 2A is formed, an extremely smooth fishing line guide surface can be formed, and the fishing line is smoothly guided. can do. In addition, it is possible to prevent thread breakage and damage to the fishing line, and the fishing line can be used for a long period of time.

  In addition, by performing the polishing step both before and after forming the carbon-doped titanium oxide layer 2A as described above, the thickness of the layer can be made uniform and the surface can be made to have a high hardness. Wear of the surface of the fishing line guide surface due to contact can be delayed. Moreover, it is possible to prevent local wear from progressing no matter which part of the fishing line guide surface comes into contact with the fishing line.

  Furthermore, in the present embodiment, by using the high hardness area of the carbon-doped titanium oxide layer 2A as the surface of the fishing line guide surface, wear of the fishing line guide surface due to the contact of the fishing line can be more reliably delayed, and over a long period of time. The fishing line can be smoothly guided (the conventional metal material cannot guide the fishing line smoothly for a long period of time).

  In the above-described configuration, as shown in FIG. 5, the thickness T of the fishing line guide portion 21 of the guide ring 26 (the thickness here is the thickness in the direction in which the fishing line slides) is set to the thickness of the frame 20. It is preferable to form a wall thickness (T> t) rather than t. In other words, it is conceivable that the portion where the fishing line comes into contact will have insufficient wear resistance as the fishing line comes into sliding contact, but by making the portion thick beforehand, it is efficient while reducing the size and weight. In addition, it is possible to improve hardness and wear resistance.

  As described above, a carbon-doped titanium oxide layer having a predetermined depth is formed over the entire surface by holding the guide ring 26 in the combustion chamber and uniformly subjecting the surface to high-temperature heat treatment. However, the depth of the carbon-doped titanium oxide layer to be formed can be changed depending on the location.

  In this case, in order to change the depth of the carbon-doped titanium oxide layer, for example, the heating temperature is changed depending on the location (how to apply the combustion flame), the heating time is changed depending on the location, or the carbon-doped titanium oxide layer is changed. It is possible to carry out by, for example, grinding a predetermined portion after the uniform is formed. Alternatively, by performing the barrel polishing described above, the amount of polishing on the side peripheral portion of the fishing line guide portion is larger than that on the fishing line guide surface 21a, and the depth of the carbon-doped titanium oxide layer can be reduced. Become.

  Thus, by forming the thickness at the side peripheral portion thinner than the thickness of the fishing line guide surface (inner peripheral surface) 21a in the fishing line guide portion 21, bending or breakage due to the improvement in hardness is caused. Even when the fishing line is caught and stress is applied during actual fishing, the frame portion can have a sticky structure (a structure in which breakage, breakage, etc. are unlikely to occur).

  In addition, as described above, the surface of the carbon-doped titanium oxide layer is modified (carbon atoms enter), and the portion has a color different from the original color of the frame (color of the titanium-based metal). Or have a pattern. Specifically, by forming a carbon-doped titanium oxide layer, the portion becomes darkened in color or pattern. Further, such dark colors and patterns can be changed depending on how the combustion flame is applied, the heating time, and the like.

  And, a portion having such a color or pattern is set as the fishing line guide surface 21a, that is, the carbon-doped titanium oxide layer formed on the fishing line guide surface 21a has a different color from the main body member other than the fishing line guide surface, or It is preferable to form it so as to have a pattern.

  In this way, by changing the color and pattern of the fishing line guide surface 21a, when the fishing line slides and wears on the portion, the color and pattern are scraped off, so that the worn state can be easily grasped. This makes it possible to easily grasp when to replace the fishing line guide.

  As described above, the carbon-doped titanium oxide layer of the guide ring 26 has a thickness of 0.1 μm or more or 0.5 μm or more, preferably 0.5 μm to 20 μm, more preferably 1.0 μm to 20 μm. Therefore, the thickness (T1) of the guide ring 26 itself can be formed in the range of 0.3 mm to 0.8 mm. That is, the wall thickness can be reduced compared with the SIC ring used in the conventional fishing line guide. In addition, if the cross-sectional shape of the guide ring 26 is circular, the above-described thickness T1 and thickness T are the same.

  In the present embodiment, the carbon-doped titanium oxide layer is not formed on the surface of the frame 20. Therefore, it is possible to give the frame itself flexibility, and to make the frame part a desired shape (substantially straight shape in the figure) so that it is difficult to break even if a fishing line is caught and stress is applied. Is possible. Moreover, in the said structure shown by FIG. 5, it is preferable to make the fixed part with the flame | frame 20 of the guide ring 26 thinner than the thickness of the carbon dope titanium oxide layer of the fishing line guide surface 21a. Thereby, it becomes possible to prevent the guide ring 26 from being cracked or broken. Further, a portion where the projections of the frame 20 are strongly pressed against a part of the outer periphery of the guide ring 26 is a main body portion (a portion where the carbon-doped titanium oxide layer is not present or a portion where the carbon-doped titanium oxide layer is thin). It is preferable to be located.

FIG. 6 is a view showing a second embodiment of a fishing line guide having a guide ring.
In this embodiment, the foot 20a is integrally formed by bending the base end side of the frame 20A. Here, the foot portion is a region fixed to the surface of the fishing rod by a thread stopper or the like, and in the figure, a range to be the foot portion 20a is indicated by a symbol Ra. Such a foot portion 20a is integrally formed when the frame 20A is formed. Similar to the structure shown in FIG. 5, the guide ring 26 is separated and the carbon-doped titanium oxide layer as described above is formed on the surface thereof. The fishing line guide 5 is manufactured by fixing this to the opening 20a of the frame 20A.

  In such a configuration, it is possible to appropriately change the material used for the frame 20A. For example, even in a portion where the fishing rod is greatly bent, it is possible to mount a fishing line guide that has the same effect as the above-described embodiment. Become.

  7 to 10 are views showing other structures of the fishing line guide. In this structure, the guide ring is integrally formed with the frame (hereinafter, these are collectively referred to simply as a frame), but of course, they may be formed separately as described above. 7 is a front view, FIG. 8 is a right side view, FIG. 9 is a view showing a state in which the fishing line guide is arranged on the fishing rod, and FIG. 10 is an assembly of the frame and the tube portion constituting the fishing line guide. It is a figure explaining a state.

  The fishing line guide 5 is provided with a cylinder part 10 in which an opening 11 to be inserted into a fishing rod R (see FIG. 9) is formed, and a frame (main body member) 20 that is held by the cylinder part 10 and through which the fishing line is inserted. Yes.

  The frame 20 has a plate shape and is integrally formed of a titanium-based material. The frame 20 is formed with a fishing line guide portion 21 into which the fishing line is inserted in a circular shape on the upper side, and a fixing portion (opening) 22 that is press-fitted and fixed to the rotation preventing portion 12 of the cylindrical portion 10 on the lower side. Is formed. As shown in FIG. 9, the upper side of the frame 20 is inclined toward the tip, so that the fishing line S can be easily pulled out in the direction of the arrow integrally with the shape of the cylindrical portion 10.

  Further, the frame 20 has a curved protrusion 25 formed radially outward of the fixing portion 22, and when the fixing portion 22 is press-fitted and fixed to the anti-rotation protrusion 12 of the cylinder portion 10, It protrudes in a curved shape from the outer surface of the part, thereby making it difficult to catch the fishing line.

  The frame 20 is preferably formed with a lightening hole 24 as needed to reduce the weight.

  The frame 20 described above can be formed by punching and then bending the upper side. After the first polishing step described above, a carbon-doped titanium oxide layer is formed on the entire surface. Has been. And after forming a carbon dope titanium oxide layer, the above-mentioned barrel grinding | polishing (2nd grinding | polishing process) is given, and the unevenness | corrugation which generate | occur | produced on the surface is grind | polished.

  The fishing line guide 5 as shown in FIG. 7 is created by press-fitting and fixing the frame 20 configured in this manner to the detent portion 12 of the cylindrical portion 10.

  The inner peripheral surface (fishing guide surface) 21a of the fishing line guide portion 21 formed on the frame 20 is a portion on which the fishing line fed out from the reel slides, and the surface of this portion is carbon-doped oxidized through the above-described manufacturing process. It is a titanium layer 2A (see FIGS. 1, 2 and 4). Since the carbon-doped titanium oxide layer 2A is formed on the surface of the inner peripheral surface (fishing line guide surface) 21a, as described above, the hardness can be improved and the wear resistance can be improved. Therefore, it is not necessary to attach the SIC guide ring, and the frame 20 can be made as small as possible. That is, in FIG. 8, even if the inner diameter D of the inner peripheral surface (fishing line guide surface) 21 a is the same as that of the conventional SIC guide ring, the fishing line guide part 21 itself is integrally formed with the frame 20. It is possible to make the width W around 21 (side peripheral portion 21b) as small as possible.

  As a result, according to the fishing line guide of the present embodiment, it is possible to obtain a configuration that can be made smaller and lighter than the conventional one and that does not damage the fishing line that is inserted. Therefore, when considering the fishing line guide attached to the tip, the hardness and wear resistance can be improved and the weight can be reduced, so that it is possible to obtain a tip that has excellent fish confidence. Further, since the frame 20 is formed with a carbon-doped titanium oxide layer having wear resistance and excellent smoothness over the entire surface portion thereof, it is possible to provide a fishing line guide that is unlikely to cause entanglement. Become.

  In particular, the upper end side of the frame 20 has a shape that is inclined so as to lie down on the tip side, and the curved protrusion 25 is formed as described above, so that it is difficult to catch a fishing line, and this Since the carbon-doped titanium oxide layer is also formed on the portion, the slidability is improved when the fishing line comes into contact, and the wear resistance is improved. Furthermore, since the carbon-doped titanium oxide layer is formed on the periphery (side peripheral portion 21b) of the fishing line guide portion 21 to improve wear resistance and smoothness (preferably, the Vickers hardness is 1000 or more. The fishing line is damaged or caught even if the fishing line from the reels is bent or bent, or even if a large load is applied due to sudden tension applied from the state of contact with moisture. Is suppressed.

  Further, in the above-described configuration, as shown in FIGS. 7 and 10, the thickness T of the fishing line guide portion 21 (the thickness here is the thickness in the direction in which the fishing line slides) is changed to the thickness t of the frame 20. It is preferable to form a thicker (T> t). In other words, it is conceivable that the portion where the fishing line comes into contact will have insufficient wear resistance as the fishing line comes into sliding contact, but by making the portion thick beforehand, it is efficient while reducing the size and weight. In addition, it is possible to improve hardness and wear resistance.

  As described above, a carbon-doped titanium oxide layer having a predetermined depth can be formed over the entire surface by holding the frame 20 in the combustion chamber and uniformly subjecting the surface to high-temperature heat treatment. Although it is possible, the depth of the carbon-doped titanium oxide layer to be formed can be changed depending on the location.

  In this case, in order to change the depth of the carbon-doped titanium oxide layer, for example, the heating temperature is changed depending on the location (how to apply the combustion flame), the heating time is changed depending on the location, or the carbon-doped titanium oxide layer is changed. It is possible to carry out by, for example, grinding a predetermined portion after the uniform is formed. Alternatively, by performing the barrel polishing described above, the polishing of the side peripheral portion (the exposed portion other than the fishing line guide surface 21a, which is indicated by reference numeral 21b) rather than the fishing line guide surface 21a in the fishing line guide portion. The amount increases and the depth of the carbon-doped titanium oxide layer can be reduced.

  As described above, the thickness of the side peripheral portion 21b is made thinner than the thickness of the fishing line guide surface (inner peripheral surface) 21a of the fishing line guide portion 21, so that the hardness is improved, so that the breakage, breakage, etc. In actual fishing, even if the fishing line is caught and stress is applied, the frame portion can have a sticky structure (a structure that does not easily break or break).

  In addition, as described above, the surface of the carbon-doped titanium oxide layer is modified (carbon atoms enter), and the portion has a color different from the original color of the frame (color of the titanium-based metal). Or have a pattern. Specifically, by forming a carbon-doped titanium oxide layer, the portion becomes darkened in color or pattern. Further, such dark colors and patterns can be changed depending on how the combustion flame is applied, the heating time, and the like.

  And, a portion having such a color or pattern is set as the fishing line guide surface 21a, that is, the carbon-doped titanium oxide layer formed on the fishing line guide surface 21a has a different color from the main body member other than the fishing line guide surface, or It is preferable to form it so as to have a pattern.

  In this way, by changing the color and pattern of the fishing line guide surface 21a, when the fishing line slides and wears on the portion, the color and pattern are scraped off, so that the worn state can be easily grasped. This makes it possible to easily grasp when to replace the fishing line guide.

  Further, the fishing line guide structure in which the guide ring 26 and the frame shown in FIG. 11 are separate includes contents that can be applied to the configurations of FIGS. 5 and 6 in particular. In the illustrated fishing line guide, a carbon-doped titanium oxide layer is formed on a guide ring 26 obtained by processing (pressing + drawing) a plate material. The carbon-doped titanium oxide layer and surface polishing are performed by the method described above. Thereafter, the guide ring 26 is fixed to the ring fixing hole 20a of the frame 20 by press-fitting or bonding (this fixing is performed after the formation of the carbon-doped titanium oxide layer). The guide ring 26 has an R chamfered portion at the fixed portion.

  In the above configuration, the thickness t of the frame 20 is 0.3 to 2.5 mm, and the width T of the guide ring 26 is equal to or larger than the thickness t of the frame 20 (t + (0.5 to 1.5 mm). Is preferable). Of course, the width T of the guide ring 26 can be made smaller than the thickness t of the frame 20. Moreover, it is preferable that thickness T1 of the guide ring 26 shall be 0.2-0.8 mm. Thus, by forming the thickness T1 of the guide ring 26 to be thinner than the thickness t of the frame 20, it is beneficial to reduce the weight and size. Further, when the thickness T1 of the guide ring 26 is formed to be thinner than the thickness t of the frame 20, it is assumed that T1 = t × (0.2 to 0.8) and the minimum thickness is 0.2 mm. It is preferable when forming a doped titanium oxide layer.

  Further, by forming the thickness T1 of the guide ring 26 thinner than the thickness t of the frame 20 as described above, it is possible to further reduce the weight and size, and further increase the inner diameter D of the guide ring 26. Thus, the fishing line can be easily guided. Further, by setting the thickness t of the frame 20 <the width T of the guide ring 26, the yarn guideability can be further improved. Moreover, since the surface which receives a fishing line can be expanded, abrasion can be prevented.

  In the above configuration, the guide ring 26 having the carbon-doped titanium oxide layer formed thereon is fixed to the frame 20. However, the carbon-doped titanium oxide layer is previously formed on the frame 20, and the guide ring is guided to the frame 20. 26 may be fixed. When the carbon-doped titanium oxide layer is formed on each of the guide ring 26 and the frame 20, the carbon-doped titanium oxide layer of the guide ring 26 is formed thick (particularly the fishing line guide surface 21a), and the carbon-doped titanium oxide layer of the frame 20 is formed. Is preferably made thinner than that of the guide ring 26. Thereby, the crack of the flame | frame 20 can be prevented. The surface hardness of the carbon-doped titanium oxide layer is preferably such that the guide ring 26 is hard and the frame 20 is lower than the guide ring 26.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to above-described embodiment, It can change variously. For example, for the titanium-based material used as the main body member, it can be changed according to the site to be used, and the depth and hardness of the carbon-doped titanium oxide layer formed on the surface, as needed, It is possible to deform.

  Further, the configuration of the shape, size, etc. of the frame portion of the fishing line guide can be appropriately modified according to the fishing rod used and the node portion (general rod, middle rod, tip rod). Furthermore, the present invention can be applied to a portion for guiding a fishing line, such as a bale and a line roller used for a reel.

The typical side view which shows the state which modified | denatured the surface of the main body member which comprises the guide ring of a fishing line guide. The expanded sectional view which showed typically the state which made the fishing line slidably contact. The expanded sectional view which shows typically the state in which the carbon dope titanium oxide layer was formed. The expanded sectional view which shows typically the state which performed the predetermined | prescribed grinding | polishing process in the state shown in FIG. The front view which shows 1st Embodiment of the fishing line guide which has a guide ring which concerns on the 1st Embodiment of this invention. The front view which shows 1st Embodiment of the fishing line guide which has a guide ring which concerns on the 2nd Embodiment of this invention. The front view which shows the other structure of a fishing line guide. The right view which shows the fishing line guide of FIG. The figure which shows the state which has arrange | positioned the fishing line guide of FIG. 7 to the fishing rod. The figure explaining the assembly state of the flame | frame and cylinder part which comprise the fishing line guide of FIG. FIG. 7 is a cross-sectional view of a fishing line guide structure in which a guide ring and a frame are separated from each other, in particular including contents applicable to the configurations of FIGS. 5 and 6.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Main body member 2A Carbon dope titanium oxide layer 5 Fishing line guide 10 Tube part 20, 20A Frame 20a Foot part 21 Fishing line guide part 21a Fishing line guide surface 26 Guide ring (main body member)

Claims (8)

A fishing line guide comprising a guide ring made of a titanium-based material and having a carbon-doped titanium oxide layer formed on the surface of a main body member having a fishing line guide portion, and a frame to which the guide ring is attached,
The carbon-doped titanium oxide layer includes a state in which titanium and carbon are bonded, and is formed to have a hardness higher than that of the titanium-based material, and the surface is processed in a state in which unevenness is polished by a polishing process. A fishing line guide characterized by The body member is formed in a plate shape,
Forming the carbon-doped titanium oxide layer on the radially outer side circumferential portion of the fishing line guide portion formed on the main body member and the fishing line guide surface of the fishing line guide portion;
The fishing line guide according to claim 1, wherein the polishing step is performed so that the surface hardness of the carbon-doped titanium oxide layer is higher than 1000 in terms of Vickers hardness.   3. The fishing line guide according to claim 1, wherein the carbon-doped titanium oxide layer is formed such that a thickness of a side peripheral portion thereof is thinner than a thickness of the fishing line guide surface.   3. The fishing line guide according to claim 1, wherein the carbon-doped titanium oxide layer formed on the fishing line guide surface has a color or a pattern different from that of the main body member other than the fishing line guide surface.   The carbon-doped titanium oxide layer is formed so that a ratio of a state in which carbon and titanium are combined is relatively larger on the surface side than on the inner side in the thickness direction. Item 5. The fishing line guide according to any one of Items 1 to 4. A method of manufacturing the guide ring of a fishing line guide comprising attaching a guide ring to a frame,
A first polishing step of polishing a plate-shaped main body member formed of a titanium-based material and having a fishing line guide portion formed thereon;
Forming a carbon-doped titanium oxide layer on the surface of the body member;
A second polishing step of polishing the surface irregularities generated when the carbon-doped titanium oxide layer is formed into a flat shape;
A method for manufacturing a guide ring, comprising:   The guide ring manufacturing method according to claim 6, wherein the second polishing step is barrel polishing.   The method for manufacturing a guide ring according to claim 6 or 7, further comprising a grinding step of partially grinding the formed carbon-doped titanium oxide layer after the second polishing step.

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