JP3445630B2 - Evaluation method of deflection characteristics of golf club shaft - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a method for evaluating the deflection characteristics of a golf club shaft.

[0002]

[Prior Art and Problems Thereof]
No. 905 proposed a new method for measuring the deflection characteristics of golf clubs. In this measurement method, the butt (grip) side of the club shaft is fixed, and the load is applied to the tip (free end) side of the club shaft. An intersection with the vertical axis is obtained, and a distance from a specific point on the fixed end side or the free end side of the club shaft to this intersection is obtained and used as a deflection characteristic value. Since this flexure characteristic value has a dimension of distance (length), it is possible to intuitively grasp the easily bendable portion of the club shaft. For example, when this distance λ is calculated with the fixed side of the club shaft as a reference, a small λ means a large bend from a position close to the bat side, and a large λ means a position close to the tip side. Means a large bend, and an intermediate value means an intermediate value between the two.

However, as a result of subsequent research, this flexure characteristic value shows a flexure characteristic when the entire club shaft is macroscopically viewed. However, the flexure characteristic value when viewed microscopically, that is, at each point in the longitudinal direction of the club shaft. It has been found to be insufficient to exhibit flexural properties.

[0004]

SUMMARY OF THE INVENTION The present invention is based on such a background, and the flexural characteristics of the club shaft are made microscopic in the longitudinal direction thereof.
The purpose is to obtain an evaluation method that can be evaluated .

[0005]

SUMMARY OF THE INVENTION The present invention has been completed based on the idea that the flexural characteristics of a club shaft can be microscopically evaluated in the lengthwise direction by examining the curvature distribution in the lengthwise direction, and includes the following steps. It is characterized by that. That is, the step of fixing the grip side of the club shaft and bending the club shaft by applying a load to the free end side of the club shaft, the displacement amount from the neutral position of the neutral axis of the club shaft in this loaded state, A step of measuring in the length direction, a step of obtaining an approximate curve of the deflection curve of the loaded club shaft from the measurement result, and a step of obtaining a curvature curve indicating a change in the curvature of the club shaft in the length direction from the approximate curve Including this, the curvature curve obtained at the end facilitates bending of the club shaft.
Evaluate the part .

According to these steps, the curvature curve in the length direction of the club shaft can be easily and surely obtained. With this curvature curve, the micro-deflection characteristic at each point of the club shaft can be intuitively grasped. be able to.

Further, the present inventor has found that the centroid of this curvature curve matches the above λ. That is, by additionally providing the step of obtaining the centroid of the curvature curve, the bendable portion of the club shaft can be evaluated at the distance from the fixed-side origin to this centroid. That is,
The distance from the intersection of the tangent line at the load point of the flexure curve under load and the neutral axis at no load to a specific point on the fixed end side of the club shaft was measured substantially. Thus, the macro deflection characteristic value proposed by the present applicant can be easily measured. The amount of displacement of the club shaft from the neutral axis can be sampled and measured at regular intervals, and an approximate curve of the deflection curve can be obtained by, for example, the least square method.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The method of the present invention will be described below with reference to the drawings. Now, fix the grip side of the club shaft into a cantilever. The position of the intersection of the tangent line at the load point of the deflection curve of this cantilever and the neutral axis when there is no load is uniquely determined, and the position of this intersection can be expressed by the dimension of length. Easy-to-bend part, tone)
Can be intuitively known. The above-mentioned Japanese Patent Application No. 4-42905 uses this characteristic to measure the deflection characteristic of the club shaft.

FIG. 1 is a conceptual diagram thereof, in which the grip G side of the club shaft 11 is fixed to form a cantilever beam, and the length direction of the club shaft 11 (length s ₀ ) is x.
Consider the y coordinate system. A constant load W is applied to the free end T of the club shaft 11 to bend the club shaft 11. Next, the tangent line at the point of action W of the load on the deflection curve (club shaft 11) or the point Q (position of x = s) distant from the point of action W of the load by an arbitrary distance, and Find the intersection R with the neutral axis x. Then, with the distance λ of the intersection R from the fixed end O, 0 ≦
The deflection characteristic (tone) in x ≦ s is set. Therefore, s
= S ₀ represents the deflection characteristic from the fixed end to the load point, and Japanese Patent Application No. 4-42905 corresponds to this case.

This λ is irrelevant to the magnitude of the load W in the range of minute deformation of the club shaft 11, and as shown in FIG. 2, the magnitudes of λ are λ _a and λ _b.
The overall flexural properties of the can be expressed. Note that, in FIG. 2, for convenience, the case where the displacement amount δ is constant is illustrated, but even if λ is compared without making δ constant, this generality is not lost.

Therefore, the club shafts 11a and 11b having the same deflection characteristic value λ can be evaluated in the same manner. In other words, the deflection characteristics of the club shaft group are macroscopically: small λ means large bending near the bat side, large λ means large bending near the tip side, and intermediate λ Being a value of can be classified as being in between.

According to the present invention, in addition to the above-described measurement of the macroscopic flexure characteristic of the club shaft by λ, the flexure characteristic is microscopically measured by drawing a curvature curve of the club shaft.

FIG. 3 shows two deflection curves 11 having the same λ.
a and 11b are schematically shown, and FIG.
The curvature curves 11a "and 11b" of 1a and 11b are schematically shown. As described above, in the club shaft 11 having different bending stiffness distributions, the curvature curves may be different even if λ is the same.

According to the present invention, in order to obtain the curvature curve of the club shaft, as shown in FIG. 1, the grip G side of the club shaft 11 is fixed, and a load W is applied to the free end side of the club shaft 11 to fix the club shaft. Bending, the amount of displacement from the neutral axis x of the club shaft in this loaded state is measured in the lengthwise direction, and an approximate curve of the deflection curve of the club shaft 11 in the loaded state is obtained from this measurement result, and this approximate deflection is obtained. From the curve, a curvature curve indicating the change in the curvature of the club shaft in the length direction is obtained.

A more specific description will be given below. As shown in FIG. 1, the club shaft 11 having the grip side fixed thereto has an extension direction (x direction) on the club shaft 11 as shown in FIG.
A guide rail 20 is provided parallel to the guide rail 20, and a laser length measuring device 21 is movably provided along the guide rail 20. The laser length measuring device 21 is a well-known device that emits a laser beam toward the object to be measured and measures the distance from the reflected light to the object to be measured. In this example, the load W is not applied to the club shaft 11. At the neutral position (x-axis)
The displacement amount y (x) when the load W is applied is measured. The value y (x) (0 ≦ x ≦ s) is measured by sampling every constant distance (for example, 15 mm) of the club shaft 11.

Next, the curvature curve of the club shaft 11 is approximately obtained from the y (x) value. Now, if a 6th-order polynomial is used as the approximate deflection curve, y (x) = a ₆ x ⁶ + a ₅ x ⁵ + ... a ₁ x + a ₀ coefficient a of this 6th-order function ₆ , a ₅ , ..., A ₀ can be determined by the method of least squares with respect to the measured value y (x). on the other hand,
Between the deflection curve y (x) and the curvature 1 / ρ (x), in the range where the deformation amount of the club shaft 11 is small,

[Equation 1] Have a relationship. That is, the curvature curve can be obtained by differentiating the deflection curve y (x) twice.

Therefore, when the approximate deflection curve y (x) is differentiated twice, y '(x) = 6 · a ₆ x ⁵ + 5 · a ₅ x ⁴ + ... 2 · a ₂ x + a ₁ y ^″ (x) = 5 · 6 · a ₆ x ⁴ + 4.5 · a ₅ x ³ + ·
· · · · · · 1 · 2 · a ₂ curvature curve obtained by the second derivative, since illustrates the change in curvature in the longitudinal direction of the club shaft 11, the deflection characteristics of the club shaft 11 in the micro Can be shown. In FIG. 1, ρ (x) is the radius of the circle of curvature at any x coordinate on the flexure curve, and S is the center thereof.

5, 6, and 7 show the club shaft 11
An example of the approximate deflection curve obtained by the actual measurement is shown, and FIGS. 8, 9, and 10 show the curvature curves obtained from the approximate deflection curve. That is, FIG. 5 shows approximate deflection curves R1, R2, and R3 obtained for three club shafts 11 having the conventional hardness notation “R”, and FIG. 6 shows the same “S”.
3 shows the approximate deflection curves S1, S2, S3 obtained for the three club shafts 11 of FIG. 7, and FIG. 7 shows the approximate deflection curves X1 obtained for the three club shafts 11 of "X",
X2 and X3 are shown. With this approximate deflection curve, it is difficult to easily find the difference between the club shafts 11.

On the other hand, FIG. 8 shows three curvature curves R1 ", R2" and R obtained from the three approximate deflection curves of FIG.
3 "and FIG. 9 shows three curvature curves S1", S2 ", S3" obtained from the three approximate deflection curves of FIG.
Fig. 10 shows three curvature curves X1 ", X2", X3 "obtained from the three approximate deflection curves of Fig. 7. These curvature curves are different from the approximate deflection curves for each club. The change in the curvature of the shaft 11 in the length direction is represented, and the micro flexural characteristic is represented with respect to the macro flexural characteristic value λ.

Further, when the present inventors have found the centroid of this curvature curve, they have found that the distance from the origin O is equal to the above λ.

11, the area of the curvature curve 11 "of the club shaft 11 is A, and the x coordinate of the centroid is x ^* . Then, from the definition of the centroid,

[Equation 2] That is, when the centroid of the curvature curve 11 ″ is obtained, it is directly used as the value of λ. Therefore, according to the present invention, the micro-deflection characteristic of the club shaft 11 can be obtained by first obtaining the curvature curve. Then, by obtaining the centroid of this curvature curve, it is possible to obtain the above-mentioned λ that is the macro-deflection characteristic of the club shaft 11.

8 to 10, R1 to R3,
The centroid positions of S1 to S3 and X1 to X3 are represented by λ _R1 to λ _R3 , λ _S1 to λ _S3 , and λ _X1 to λ.
_Expressed as _X3 .

[0023]

As described above, according to the method of the present invention, it is possible to intuitively evaluate the flexural characteristics of the club shaft, particularly where the microscopically bendable portion is located.

By measuring the flexural characteristics in this way, it becomes possible to manufacture, for example, a golf club shaft having characteristics close to those of existing golf club shafts with high reproducibility, which relies on the feeling of a conventional expert. The manufacturing of golf club shafts can be transformed into a scientific manufacturing method.

[Brief description of drawings]

FIG. 1 is a skeleton diagram illustrating the principle of a method for measuring the flexural characteristic of a club shaft according to the present invention.

FIG. 2 is a skeleton diagram showing a deflection characteristic example of a club shaft according to λ.

FIG. 3 is an explanatory diagram showing an example of deflection curves having the same λ and different shapes.

FIG. 4 is an explanatory diagram showing an example of a curvature curve of the deflection curve of FIG.

FIG. 5 is a flexure curve diagram showing an example of approximate flexure curves of three club shafts having hardness R.

FIG. 6 is a flexure curve diagram showing an example of approximate flexure curves of three club shafts having hardness S.

FIG. 7 is a flexure curve diagram showing an example of approximate flexure curves of three club shafts having a hardness X.

8 is a curvature curve diagram obtained from the three approximate deflection curves in FIG.

9 is a curvature curve diagram obtained from the three approximate deflection curves in FIG.

10 is a curvature curve diagram obtained from the three approximate deflection curves in FIG.

FIG. 11 is an explanatory diagram illustrating that the x coordinate of the centroid of the curvature curve is equal to λ.

[Explanation of symbols]

11 11a 11b Club shaft (deflection curve) 11 ”curvature curve 20 Guide rail 21 Laser length measuring machine

Claims (2)

(57) [Claims] 1. A step of fixing the grip side of a golf club shaft and bending the club shaft by applying a load to the free end side thereof; displacement from the neutral position of the neutral axis of the club shaft in this loaded state. A step of measuring the amount in the length direction thereof; a step of obtaining an approximate curve of the flexure curve of the loaded club shaft from the measurement result; and a change in the longitudinal direction of the club shaft curvature from the approximate flexure curve. A method of evaluating the deflection characteristics of a golf club shaft, which comprises: a step of obtaining a curvature curve; and evaluating a bendable portion of the club shaft with the curvature curve. 2. The method for evaluating the flexural characteristic according to claim 1.
The amount of displacement from the neutral position of the neutral axis of the club shaft is sampled and measured at regular intervals to evaluate the deflection characteristics of the golf club shaft.