JP7372404B2 - Golf club head alloy, golf club head and golf club head alloy heat treatment method - Google Patents

Description

The present invention relates to an alloy for golf club heads, and more particularly to an alloy for golf club heads having high strength, a golf club head cast from this alloy for golf club heads, and a heat treatment method for this alloy for golf club heads. It is.

Titanium alloys are widely used as casting materials for golf club heads because they have good strength, corrosion resistance, and heat resistance.
For example, conventional 811 titanium alloy consists of about 8% aluminum, about 1% vanadium, about 1% molybdenum, and the balance titanium and unavoidable impurities. Golf club heads manufactured from titanium alloys have better strength and can provide users with a more favorable hitting feel.

Nowadays, as users seek better hitting feel and stronger hitting power, golf club heads made from conventional 811 titanium alloy are facing the problem of insufficient strength. .
Therefore, those skilled in the art will adjust the composition of the conventional 811 titanium alloy to remove molybdenum, leaving about 7.5% by weight aluminum, about 4.5% vanadium, about 1.2% chromium, and the balance. A titanium alloy (140C titanium alloy) was made of titanium and inevitable impurities.
As a result, the golf club head manufactured from the 140C titanium alloy has higher strength than the 811 titanium alloy.
However, in manufacturing golf club heads using 140C titanium alloy, the molding rate was extremely low, making it difficult to widely use it.
In view of the above, conventional alloys for golf club heads need to be improved.

Taiwan No. I569855

In order to solve the above problems, an object of the present invention is to provide an alloy for golf club heads, in which the golf club head manufactured by the alloy for golf club heads has better strength.

A further object of the present invention is to provide an alloy for golf club heads that improves the molding rate of golf club heads.

Another object of the present invention is to provide a golf club head that has an even better hitting feel.

A further object of the present invention is to provide a method of heat treating an alloy for a golf club head, which improves the strength of a golf club head manufactured using the alloy for a golf club head.

The numerals such as "one" or "one piece" used in the parts or components of the present invention are used for convenience and are given their usual meaning with respect to the claims of the present invention. or at least one, and unless a different meaning is clearly indicated, the meaning of one also includes the plural.

The alloy for golf club heads according to the present invention consists of 8 to 9% by weight of aluminum, 3.5 to 4.5% by weight of vanadium, 1 to 2% by weight of molybdenum, the balance being titanium, and unavoidable impurities. It is characterized by

The golf club head according to the present invention is characterized in that it is formed by casting using the above alloy for golf club heads.

The heat treatment method for an alloy for golf club heads according to the present invention provides the above-mentioned alloy for golf club heads as an alloy base material, heats the alloy base material, and heats the alloy base material at 450 to 750° C. The aging treatment is performed by maintaining it for 2 hours, and the temperature of the aged alloy base material is lowered to room temperature by cooling the aged alloy base material for 10 to 20 minutes with a quenching medium. include.

Further, the alloy for golf club heads can form a titanium alloy, and when a golf club head is cast using this titanium alloy as a casting material and subjected to the above heat treatment, a golf club head with good strength can be formed. I can do it.
As a result, the alloy for golf club heads of the present invention can have stable α and β phases depending on the composition ratio of the above metals, so that the quality of the golf club head can be improved. I can do it.
Furthermore, compared to 811 titanium alloy and 140C titanium alloy, the present invention has better mechanical properties.
In addition, the golf club head manufactured using the golf club head alloy of the present invention has better golf club head forming rate and mechanical properties, improves yield, and achieves the effect of having a good hitting feel.
In addition, the method for heat treating an alloy for golf club heads of the present invention involves casting a golf club head using an alloy base material and performing heat treatment (e.g., aging treatment and quenching treatment). Compared to a club head, a golf club head manufactured using an alloy base material subjected to such heat treatment can further improve mechanical properties and has the effect of further improving the strength of the golf club head.

The golf club head alloy may also include 8.5% aluminum by weight.
Accordingly, when a golf club head is manufactured from the golf club head alloy, it is possible to have a better forming rate and strength.

The golf club head alloy may also include 4% by weight vanadium.
Accordingly, when a golf club head is manufactured from the golf club head alloy, it is possible to have a better forming rate and strength.

The golf club head alloy may also include 1% by weight molybdenum.
Accordingly, when a golf club head is manufactured from the golf club head alloy, it can have better strength and formability.

Additionally, the golf club head alloy can include ≦1% by weight tantalum.
Accordingly, when a golf club head is manufactured from the golf club head alloy, it can have better strength and formability.

The golf club head can also have a tensile strength of 150 to 169 ksi and a yield strength of 138 to 156 ksi.
This has the effect of improving the quality of the golf club head.

Also, the golf club head can have a density of 4.401 to 4.413 g/cm ³ .
This has the effect of improving the quality of the golf club head.

Further, when aging treatment is performed on the alloy base material, the temperature of the aging treatment may be 580 to 620° C., and the time of the aging treatment may be 1 hour.
This has the effect of further improving the mechanical properties of the alloy base material.

Further, the quenching medium may be a neutral gas or an inert gas.
This makes it possible to avoid changes in the metal structure of the alloy base material, thereby avoiding deterioration of the mechanical properties of the alloy base material.

Embodiments of the present invention will be described below with reference to the drawings.

An embodiment of the golf club head alloy of the present invention is made of aluminum (Al), vanadium (V), molybdenum (Mo), the balance being titanium, and inevitable impurities.
As a result, the golf club head alloy can be a titanium alloy, and this titanium alloy can be used as a cast material to form a golf club head with good strength.

Specifically, aluminum can stabilize the alpha phase of titanium alloys, so adding aluminum to a golf club head alloy improves the forming rate of golf club heads manufactured from this golf club head alloy. be able to.
However, too much aluminum will cause the golf club head to become brittle, and too little aluminum will reduce the molding rate.
As a result of the adjustment, the golf club head alloy of the present invention contains 8-9% by weight of aluminum.
In one example, the golf club head alloy includes 8.5% aluminum by weight, which provides better formability and strength when golf club heads are manufactured from the golf club head alloy.

Vanadium is an isomorphic element of the element that stabilizes the β phase.
Vanadium has better solid solubility in the beta phase.
That is, when vanadium is dissolved in the crystal lattice of the alloy, it can maintain the stability of the crystal lattice, so adding vanadium to the alloy for a golf club head can improve the strength of the golf club head.
However, if the amount of vanadium is too large, the molding rate of the golf club head will be reduced, and if the amount is too small, the desired mechanical strength will not be obtained.
As a result of the adjustment, the golf club head alloy of the present invention contains 3.5 to 4.5 weight percent vanadium.
In one example, the golf club head alloy includes 4% by weight vanadium, which has better formability and strength when golf club heads are manufactured from the golf club head alloy.

Molybdenum can stabilize the β phase of a titanium alloy, so adding molybdenum to an alloy for a golf club head can improve the strength of the golf club head.
Thus, golf club head alloys contain 1-2% by weight molybdenum.
In one example, the golf club head alloy includes 1% molybdenum by weight, which provides better strength to the golf club and improves the golf club head when the golf club head is manufactured from the golf club head alloy. The molding rate of the club head can be improved.

The golf club head alloy further includes tantalum (Ta).
Tantalum can stabilize the β phase of titanium alloys, so adding tantalum to golf club head alloys can improve the strength of golf club heads. It does not reduce the molding rate.
Thus, the golf club head alloy contains ≦1% by weight of tantalum, which can provide better strength to the golf club and improve the forming rate of the golf club head.

It should be further explained that similar mechanical properties can be obtained by appropriately adjusting the composition of the golf club head alloy of the present invention.
In one embodiment, the golf club head alloy of the present invention comprises aluminum, vanadium, molybdenum, tantalum, titanium, and unavoidable impurities, with aluminum accounting for 8% to 9% by weight and vanadium 3. Molybdenum accounts for 1% to 2% by weight , and tantalum accounts for 0.5% to 1.5% by weight .

Further, when manufacturing the alloy for golf club heads of the present invention, an ingot of the above-mentioned metal element or a master alloy containing the above-mentioned metal is melted and mixed in a high-temperature furnace or a high-frequency furnace, thereby containing the metal in the above-mentioned weight percent. An alloy substrate can be formed.
This allows this alloy substrate to be used in casting golf club heads.

Furthermore, the alloy base material of the present invention can be heat treated.
For example, this heat treatment is a heat treatment process in which the temperature is raised by aging treatment and then lowered by quenching treatment.
The aging treatment is performed by maintaining the alloy base material at 450 to 750° C. for 0.5 to 2 hours.
In one embodiment, the alloy substrate is aged by maintaining it at 580-620° C. for 1 hour.
As for the quenching treatment, following the above-mentioned aging treatment, the temperature of the alloy base material is lowered to room temperature by cooling the aged alloy base material for 10 to 20 minutes using a quenching medium.
The quenching medium may be, for example, water, oil, an aqueous inorganic salt solution, an aqueous organic salt solution, or a gas.
In one embodiment, the quenching medium is a neutral gas (eg, nitrogen) or an inert gas (eg, helium or argon).
This makes it possible to avoid changes in the metal structure of the alloy base material, thereby avoiding deterioration of the mechanical properties of the alloy base material.
Therefore, a golf club head cast from an alloy base material has better mechanical properties after undergoing aging treatment and quenching treatment.

In order to prove that the golf club head manufactured by the golf club head alloy of the present invention has good strength, 811 titanium alloy (first set) and 140C titanium alloy (second set) are shown in Table 1. The mechanical properties of golf club heads manufactured according to one embodiment of the present invention (third set) and another embodiment of the present invention (fourth set) were measured.
The results are shown in Table 2.

Table 1. Composition ratio (weight %) of each golf club head alloy in this test

Table 2: Mechanical properties of golf club heads manufactured from various golf club head alloys

According to the above test results, golf club heads (3rd and 4th sets) manufactured using the golf club head alloy of the present invention have both tensile strength and yield strength of 811 titanium alloy (1st set) and 140C titanium alloy. (2nd set).
Further, the golf club head manufactured by the alloy of the third group of the present invention has a density of 4.401 to 4.405 g/cm3, and the golf club head manufactured by the alloy of the fourth group of the present invention has a density of 4.401 to 4.405 g/ ^cm3 . has a density of 4.409 to 4.413 g/ ^cm3 , indicating that the golf club head manufactured by the golf club head alloy of the present invention can maintain a certain strength while having a low density. There is.
It should be further explained that similar mechanical properties can be obtained by suitably adjusting the compositions of the third and fourth sets according to demand.

In addition, the above four sets of alloys were actually used for casting, and the molding rates of the casts of each set of alloys were measured.
Briefly, when casting a golf club head, a shell mold is first created, and a liquid alloy is poured into the shell mold.
After the liquid alloy cools down, it assumes a shape that matches the mold cavity, thereby obtaining a casting.
However, in the actual production process, not all castings can perfectly replicate the shape of the shell mold.
For example, if the fluidity of the liquid alloy is poor, the casting may be damaged or cracked.
Furthermore, the molding rate of casting can be calculated from the number of defective castings.
According to experiments, the molding rate when golf club heads were cast using 140C titanium alloy (second set) was only 0-2%.
On the other hand, when golf club heads were cast using the golf club head alloys of the present invention (3rd and 4th sets), the molding rate was 86%.
As a result, according to the golf club head alloy of the present invention, not only can a golf club head with good strength be manufactured, but also the molding rate of the golf club head can be improved.

Table 3 Mechanical properties depending on temperature of different aging treatments

As shown in the table above, in this test, alloys in the third and fourth groups in Table 1 were selected and tested, and their mechanical properties were compared.
The aging treatment was divided into three test groups: first, untreated (none) as a control group, second, treated at 500°C for 1 hour as a comparison group, and third, Those treated at 600° C. for 1 hour were used as a comparison group.
As shown in Table 3, the mechanical properties of the golf club heads that were subjected to the aging treatment were improved compared to the golf club heads that were manufactured using the alloy base material that was not subjected to the aging treatment.
Further, when the aging treatment is performed at a temperature of 600° C. for 1 hour, the golf club head manufactured by the golf club head alloy can have better mechanical properties than when the aging treatment is performed at a temperature of 500° C.

As described above, the alloy for golf club heads of the present invention can have stable α phase and β phase due to the composition ratio of the above metals, and furthermore, the alloy for golf club heads can be manufactured by the alloy for golf club heads. The golf club head according to the present invention may have better mechanical properties than the 811 titanium alloy and the 140C titanium alloy, and has the effect of improving the quality of the golf club head.
In addition, the golf club head manufactured using the golf club head alloy of the present invention has better golf club head forming rate and mechanical properties, improves yield, and achieves the effect of having a good hitting feel.

In addition, the heat treatment method for golf club head alloys of the present invention involves casting a golf club head using an alloy base material and subjecting it to aging treatment and quenching treatment. , it is possible to further improve the mechanical properties of the golf club head, and has the effect of further improving the strength of the golf club head.

The invention may be embodied in other ways without departing from its spirit or essential characteristics.
Accordingly, the embodiments described herein are illustrative and do not limit the scope of the invention.

Claims (11)

An alloy for golf club heads characterized by comprising 8 to 9% by weight of aluminum, 3.5 to 4.5% by weight of vanadium, 1 to 2 % by weight of molybdenum, the balance being titanium, and unavoidable impurities. The golf club head alloy of claim 1, comprising 8.5% by weight aluminum. 3. The golf club head alloy of claim 2, comprising 4% by weight vanadium. 4. The golf club head alloy of claim 3, comprising 1% by weight of molybdenum. The golf club head alloy of claim 1 further comprising ≦1% by weight tantalum. A golf club head, characterized in that it is formed by casting using the golf club head alloy according to any one of claims 1 to 5. 7. The golf club head of claim 6, having a tensile strength of 150 to 169 ksi and a yield strength of 138 to 156 ksi. A golf club head according to claim 6, characterized in that it has a density of 4.401 to 4.413 g/cm ³ . Providing the alloy for a golf club head according to any one of claims 1 to 5 as an alloy base material,
Aging treatment is performed by heating the alloy base material and maintaining the alloy base material at 450 to 750 ° C. for 0.5 to 2 hours,
A method for heat treating an alloy for a golf club head, the method comprising cooling the aged alloy base material for 10 to 20 minutes with a quenching medium to lower the temperature of the aged alloy base material to room temperature. The golf club head according to claim 9, wherein when aging treatment is performed on the alloy base material, the temperature of the aging treatment is 580 to 620° C., and the time of the aging treatment is 1 hour. Heat treatment method for alloys for use. 10. The method of heat treating an alloy for a golf club head according to claim 9, wherein the quenching medium is a neutral gas or an inert gas.