JPS6341532B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application This invention relates to a guide used to guide a fishing line in fishing gear such as a fishing rod.

BACKGROUND OF THE INVENTION Traditionally, most fishing line guides have been made of carbon steel with hard chrome plating. However, such a guide has a problem in that the plating peels off and rusts when it hits or rubs against rocks, sand, etc.

On the other hand, in recent years, guides using alumina ceramics or silicon carbide ceramics have also been proposed. These ceramic guides have the advantage of not having to worry about rusting, but alumina ceramics and silicon carbide ceramics have poor mechanical properties, especially toughness, and poor impact resistance, so if the fishing gear is dropped on rock, In such cases, problems such as cracking or chipping often occur.

Problems to be Solved by the Invention The purpose of the present invention is to solve the above-mentioned problems of conventional guides, and to provide a fishing line guide that not only has high strength, toughness, and impact resistance, but also has excellent durability. is to provide.

Means for Solving the Problems In order to achieve the above object, the present invention is characterized in that at least the portion in contact with the fishing line is made of a zirconia sintered body, and the zirconia sintered body is (a) a cubic system crystal; (b) contains at least 70 mol% of zirconia with a tetragonal crystal structure; (c) contains 10 mol% or less of zirconia with a monoclinic crystal structure; (d) The fishing line guide is characterized by having an average crystal grain size within the range of 0.2 to 1 μm, and (e) having a porosity calculated from theoretical density and actual density of 2% or less. Here, the fishing line guide is a general term for guides that guide fishing lines in various fishing gear such as fishing rods and fishing reels.

In this invention, all or part of the fishing line guide (for example, the line guide ring in a case where the line guide ring is fitted to a holder) is made of a zirconia sintered body. In short, it is sufficient that the portion that the fishing line comes into contact with is made of a zirconia sintered body.

The zirconia sintered body includes zirconia having a cubic crystal structure (cubic zirconia),
Contains at least 70 mol% of zirconia with a tetragonal crystal structure (tetragonal zirconia) and 10 mol% or less of zirconia with a monoclinic crystal structure (monoclinic zirconia).

By using a zirconia sintered body containing cubic zirconia, the heat resistance of the fishing line guide is improved. Improving heat resistance is very important because the surface temperature of a fishing line guide can reach 300 to 400°C due to friction from the fishing line. The reason why heat resistance is improved by the presence of cubic zirconia can be explained as follows.

In other words, the cubic zirconia of the zirconia sintered body containing at least 70 mol% of tetragonal zirconia exists around the tetragonal zirconia forming the matrix and is dispersed between the particles. When the temperature of the crystal rises under the influence of moisture, the stability of tetragonal zirconia decreases and it transforms into stable monoclinic zirconia, forming fine cracks at the grain boundaries of the tetragonal zirconia. The destruction that started from is about to proceed. However, the presence of cubic zirconia that does not undergo such transformation suppresses the progress of fracture and improves heat resistance. Since this heat resistance is a problem in the presence of moisture, etc., it can be referred to as corrosion resistance.

The fishing line guide of this invention has high strength, toughness, and excellent impact resistance, and one of the reasons for this is that
Contains at least 70 mol% of tetragonal zirconia,
The reason is that a zirconia sintered body containing monoclinic zirconia of 10 mol% or less is used.

That is, tetragonal zirconia transforms into monoclinic zirconia when subjected to stress. This is a stress-induced transformation. Therefore, if a zirconia sintered body containing tetragonal zirconia is used, even if stress is applied to it, the stress will be alleviated by the amount of energy required for the transformation of the tetragonal zirconia, and the strength of the sintered body will be improved by that amount. be. Improved strength also means improved toughness. Therefore, if a large amount of tetragonal zirconia of at least 70 mol % is contained, the stress-induced transformation mechanism described above will function sufficiently, and strength and toughness will be greatly improved, and high impact resistance will be obtained.

Thus, by using a zirconia sintered body containing at least 70 mol% of tetragonal zirconia, it is possible to greatly improve the strength and toughness of the fishing line guide, as well as the impact resistance. Not only does it not have such an effect, but the fact that it contains monoclinic zirconia means that microcracks occur around or near it due to the transformation of the crystal structure from tetragonal to monoclinic. Therefore, if such a sintered body is subjected to stress, fracture starting from microcracks may progress, so in this invention, a sintered body containing 10 mol% or less of monoclinic zirconia is used. is used.

In the above, the amount C _T mol% of tetragonal zirconia is the cubic zirconia obtained by X-ray diffraction of the surface of the fishing line guide that is in contact with the fishing line.
Diffraction intensity of 400 plane and tetragonal zirconia 004 plane and
It is calculated from the diffraction intensity of the 220 plane using the following formula. However, as the diffraction intensity, a value after correction by the Lorentz factor is used.

C _T = [(I _T004 + I _T220 ) / (I _C400 + I _T004 + I _T220 )] × 100 However, I _T004 : Diffraction intensity of the 004 plane of tetragonal zirconia I _T220 : Diffraction intensity of the 220 plane of tetragonal zirconia I _C400 : Cubic Diffraction intensity of 400 planes of crystalline zirconia Similarly, the amount of monoclinic zirconia, C _M mol%, is determined by the following formula.

C _M = [(I _M111 + I _M111 ) / (I _T111 + I _M111 + I _M111 )] × 100 where I _M111 : Diffraction intensity of monoclinic zirconia 111 plane I _M111 : Diffraction intensity of monoclinic zirconia 111 plane I _T100 : Diffraction intensity of 111 planes of tetragonal zirconia Once the amounts of tetragonal zirconia and monoclinic zirconia are determined, the remainder is cubic zirconia.

Now, in this invention, in addition to having the above-mentioned specific crystal structure, the average crystal grain size is
A zirconia sintered body having a diameter of 0.2 to 1 μm is used.
This is a necessary condition for obtaining a fishing line guide with high strength, toughness, and excellent impact resistance.

That is, the above-mentioned stress-induced transformation of tetragonal zirconia largely depends on the crystal grain size, and transformation is difficult to occur when the grain size is less than 0.2 μm. This is thought to be because the particle size is too fine, so that the nuclei necessary for transformation are not generated, and the elastic strain energy becomes large, making the tetragonal structure stable. If stress-induced transformation is suppressed, improvements in strength, toughness, and even impact resistance can no longer be expected. On the other hand, if the thickness exceeds 1 μm, the transformation of the crystal structure from tetragonal to monoclinic will be significantly accelerated during the cooling process after sintering, and the sintered body will eventually contain a large amount of monoclinic zirconia. Become. Therefore, the strength of the sintered body is greatly reduced and it can no longer be used as a constituent material for fishing line guides. Furthermore, it becomes unstable against moisture, etc., and its corrosion resistance decreases.

In this invention, a zirconia sintered body having a porosity of 2% or less is used. Here, the porosity P
(%) is defined by the formula: P=[1-(actual density/theoretical density)]×100. Therefore, the lower the porosity, the better the strength, toughness, and impact resistance of the zirconia sintered body and, ultimately, of the fishing line guide.

In other words, pores mainly occur at grain boundaries, and the pores reduce the bonding area between crystal grains and reduce the bonding force between the grains. Also,
If pores exist, the applied stress will be concentrated in the pores. A decrease in bonding strength itself reduces the strength, toughness, and impact resistance of the sintered body, but if stress concentrates in the pores and that part breaks, the destruction will occur due to the weak bonding force between particles. It spreads easily, and its strength, toughness, and impact resistance decrease at an accelerating rate. Furthermore, when stress is concentrated in the pores, the stress acting on the crystal grains is reduced. However, if stress no longer acts sufficiently on the crystal grains, the above-mentioned stress-induced transformation mechanism, which is unique to zirconia sintered bodies, will no longer function sufficiently, resulting in loss of strength, toughness, etc.
Impact resistance will be greatly reduced. From this point of view, it can be said that the lower the porosity, the better; however, if it is 2% or less, there is virtually no problem.

Furthermore, by using a zirconia sintered body with a porosity of 2% or less, the corrosion resistance and heat resistance of the fishing line guide, as well as its durability, are greatly improved.

In other words, tetragonal zirconia is in a metastable state at room temperature, but when moisture and heat act on it at the same time, it becomes a trigger and tends to transform into monoclinic zirconia, resulting in an increase in the amount of monoclinic zirconia. As a result, strength, toughness, and impact resistance decrease. This is thought to be because when moisture and heat are applied simultaneously, the moisture and the stabilizer in the sintered body react, and the stability of the tetragonal structure is impaired. In addition, since moisture and heat tend to act on pores, destruction that starts from the pores and propagates along the grain boundaries tends to proceed. This inconvenience is that fishing line guides are prone to water adhesion, and the surface temperature rises due to friction with the fishing line.
The temperature can reach 300 to 400℃, so it cannot be ignored, but in this invention, the porosity is 2%.
Such inconveniences are prevented by using the following sintered bodies.

In addition, having a porosity of 2% or less is very advantageous in terms of manufacturing.

That is, the crystal structure of the zirconia sintered body is in a tetragonal system or a coexistence state of a tetragonal system and a cubic system in the firing step described below. However, tetragonal zirconia tends to transform into monoclinic zirconia during the cooling process after firing. In addition, cubic zirconia tries to transform into tetragonal zirconia and then into monoclinic zirconia, but the transformation from tetragonal to monoclinic depends on the bonding state of crystal particles, and the porosity increases. When it exceeds 2%, the bonding force between particles decreases significantly, and the metastable tetragonal structure easily changes to a monoclinic structure. In addition, the pores form free surfaces between particles where the particles are not bonded to each other, thereby reducing elastic strain energy and promoting transformation. Due to these effects, in a sintered body with a porosity exceeding 2%, transformation from a tetragonal system to a monoclinic system easily occurs.
It becomes very difficult to control the amount of tetragonal zirconia.

In this way, the porosity of a zirconia sintered body has a great relationship not only with its mechanical properties but also with its corrosion resistance, heat resistance, and even durability.

The above-mentioned zirconia sintered body is obtained by dissolving a stabilizer such as yttria, calcia, magnesia, etc. in zirconia. Among them,
It is preferable to use itria or calcia, which can be sintered at a relatively low temperature. In this case, itria may be dissolved in a solid solution of 1 to 5 mol %, and calcia may be dissolved in a solid solution of 1 to 9 mol %. Of course, Ittria and Calcia are each within the above range,
And they may be used together in a range of 2 to 10 mol% in total.

The fishing line guide of this invention can be manufactured by various methods. Next, a preferable example thereof will be shown.

That is, first, an aqueous solution is prepared in which zirconium oxychloride with a purity of 99.9% or more is mixed with yttrium chloride and/or calcium chloride in a desired molar ratio.

Next, the above aqueous solution is heated to drive off the water, and further heated to around 1000°C at a rate of 50 to 150°C/hour,
A mixed powder of zirconia and ittria and/or calcia is obtained.

Next, after pulverizing and drying the above mixed powder,
The material is calcined at around 1000°C, pulverized, an organic binder such as polyvinyl alcohol is added, granulated, and dried to obtain a raw material powder.

Next, the raw material powder is molded into the desired shape using a molding method, and then molded at a rate of 100 to 200℃/hour.
After heating to around 1000℃, further heating to around 1600℃ at a rate of 50 to 200℃/hour, and firing, 1000℃
At a rate of 200-300℃/hour until around ℃, then
Cool down to around 500℃ at a rate of 100 to 200℃/hour.
It is further cooled to room temperature and sintered.

At least the portion of the thus obtained sintered body in the shape of the desired fishing line guide or its portion that comes into contact with the fishing line is polished by barrel processing or wrapping processing.

In the above, a rubber press molding method may be used instead of the mold molding method, and the obtained molded body may be machined and then sintered. In addition, the molded body
It is also possible to use a hot isostatic sintering method in which the material is fired at 1300 to 1600°C and then sintered at 1200 to 1500°C under a pressure of 500 to 3000 Kg/cm ² .

Effects of the Invention In the fishing line guide of the present invention, at least the portion in contact with the fishing line is made of a zirconia sintered body, and the zirconia sintered body contains cubic zirconia and contains at least 70 mol% of tetragonal zirconia.
Contains 10 mol% or less of monoclinic zirconia,
The average crystal grain size is 0.2 to 1 μm, and the porosity is 2.
% or less, the strength, toughness, and impact resistance are greatly improved, and there is almost no fear of cracking or chipping even if the fishing gear is dropped on rock.It also has improved corrosion resistance and heat resistance. and improves durability. Furthermore, since zirconia sintered bodies inherently have low surface free energy and the crystal grain size can be easily controlled, the fishing line guide of the present invention can lower the coefficient of friction with the fishing line and improve wear resistance.

Claims (1)

[Scope of Claims] 1. At least the portion in contact with the fishing line is made of a zirconia sintered body, and the zirconia sintered body includes (a) zirconia having a cubic crystal structure; (b) a tetragonal crystal structure; containing at least 70 mol% of zirconia having a monoclinic crystal structure; (e) A fishing line guide characterized in that the porosity calculated from the theoretical density and the actual density is 2% or less.