JP2012239627A - Selection method and design method for golf club - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for selecting a golf club, selecting a golf club advantageous to improving a carry of a hit ball according to swing of a golfer, and a method for designing a golf club, designing such a golf club.SOLUTION: A face rotation FR when a golfer swings a golf club 10 is measured by a behavior measurement device. A center of gravity calculating means 30A calculates the position of the center of gravity point G from a correlation map 3002 based on the face rotation FR. A golf club select means 30B selects a golf club 10 based on the position of the center of gravity point G. A service provider of facility provides the optimum golf club 10 for the golfer based on the selection result of the golf club 10, or provides information (manufacturer, serial number, or the like) on the golf club 10.

Description

  The present invention relates to a golf club selection method and design method. More specifically, the present invention relates to a selection method for selecting a golf club based on a face rotation that is a displacement amount around a shaft of a face surface immediately before hitting, and golf based on a face rotation. It relates to a design method for designing a club.

Various techniques for measuring the behavior of a golf club when a golfer swings a golf club head and selecting a golf club suitable for a golfer based on the measurement result have been proposed.
For example, in the technique disclosed in Patent Document 1, a golf club having an optimal inertia characteristic specification is used based on a statistical method based on a ball initial speed measurement result obtained by swinging a basic club having a known inertia characteristic specification. Select.
In the technique disclosed in Patent Document 2, the bending behavior data is analyzed based on the measurement result of the bending moment applied to the shaft of the sample golf club, and the bending stiffness distribution suitable for the golfer is obtained based on the analysis result. Select the shaft you have.

JP 2005-278882 A JP 2003-284802 A

However, in the above-described prior art, no particular consideration is given to how the swing of the golf club affects the position on the face surface of the highest initial speed point at which the initial speed when the golf ball is hit is highest.
Therefore, the present inventors have obtained the following knowledge by paying attention to the swing of a golf club by a golfer.
That is, when the amount of displacement per unit time that the face surface is displaced around the shaft axis of the golf club immediately before the golf club head hits the golf ball is a face rotation, the velocity distribution of the face surface of the golf club head is a swing. In addition to the speed of the face, it changes under the influence of face rotation.
Therefore, even if the same golf club is swung, if the face rotation is different, the speed distribution of the face surface changes.
Therefore, if the face rotation is different and therefore the velocity distribution on the face surface is different, the position of the maximum initial velocity point when the golf ball is hit is also different.
Since the position of the maximum initial velocity point is a factor that greatly affects the flight distance of the hit ball, selection of a golf club in consideration of face rotation is considered to be effective in improving the hit distance of the hit ball. It is done.

The present invention has been made in view of such circumstances, and its purpose is to select a golf club that can select a golf club that is advantageous in improving the flight distance of a hit ball in accordance with a golfer's swing. It is to provide a method.
It is another object of the present invention to provide a golf club design method capable of designing a golf club that is advantageous in improving the flight distance of a hit ball in accordance with a golfer's swing.

  In order to achieve the above object, the golf club selection method of the present invention measures the behavior of a golf club head immediately before the golf club head of a golf club swung by a golfer hits a golf ball, and based on the measurement result. A golf club selection method, wherein the amount of displacement per unit time at which the face surface is displaced around the shaft axis of the golf club immediately before the golf club head hits the golf ball is referred to as face rotation, A straight line extending through the center in the toe-heel direction of the area defined as the area hitting the golf ball in the face surface and extending in a direction perpendicular to the toe-heel direction is defined as a face center line. Project the center of gravity perpendicular to the face A golf ball is hit with a face rotation measurement step for measuring the face rotation of a golf club swung by a golfer, and the face center line of the face surface displaced by the measured face rotation, when the point is the center of gravity. The center of gravity point calculating step for calculating the position of the center of gravity necessary for the initial speed to become the maximum initial speed is selected, and a golf club suitable for the golfer's face rotation is selected based on the calculated position of the center of gravity. A selection step.

  Further, in the golf club designing method of the present invention, the amount of displacement per unit time that the face surface is displaced around the shaft axis of the golf club immediately before the golf club head hits the golf ball is defined as face rotation, A straight line that passes through the center in the toe-heel direction and extends in a direction perpendicular to the toe-heel direction of a region defined as a region hitting a golf ball is defined as a face center line, and the center of gravity position of the golf club head is A golf ball is hit by the face rotation setting step in which the face rotation is set and the face center line of the face surface that is displaced by the set face rotation when the position projected perpendicularly to the face surface is the center of gravity. When the initial speed is the maximum initial speed A center-of-gravity point calculating step for calculating the position of the center-of-gravity point necessary to become the position of the center-of-gravity point corresponding to the set face rotation, and a design variable of the golf club head based on the calculated position of the center-of-gravity point And a design step for determining.

  According to the golf club selection method of the present invention, the position of the center of gravity necessary for the initial speed when the golf ball is hit at the face center line of the face surface displaced by the measured face rotation to be the maximum initial speed is calculated. Since the golf club suitable for the golfer's face rotation is selected based on the calculated position of the center of gravity, a golf club that is advantageous in improving the flight distance of the hit ball according to the golfer's swing is selected. can do.

  In addition, according to the golf club design method of the present invention, the position of the center of gravity necessary for the initial speed when the golf ball is hit at the face center line of the face surface displaced by the set face rotation to be the maximum initial speed. Since the design variable of the golf club head is determined based on the calculated position of the center of gravity, a golf club that is advantageous in improving the flight distance of the hit ball according to the golfer's swing is designed. be able to.

It is a front view which shows the example of the golf club head used as the object of the selection method of the golf club of this invention. 5 is an explanatory diagram showing an example of a method for defining a center point C and a face center line CL of the face surface 16; FIG. 5 is an explanatory diagram showing an example of a method for defining a center point C and a face center line CL of the face surface 16; FIG. 5 is an explanatory diagram showing an example of a method for defining a center point C and a face center line CL of the face surface 16; FIG. 5 is an explanatory diagram showing an example of a method for defining a center point C and a face center line CL of the face surface 16; FIG. 4 is a cross-sectional view of the golf club head 12 showing the relationship between the gravity center position P0 and the gravity center point P. FIG. 4 is a front view of the golf club head 12 for explaining the definition of the contour line I of the face surface 16. FIG. 4 is a cross-sectional view of the golf club head 12 for explaining the definition of the contour line I of the face surface 16. FIG. 3 is a front view of the golf club head 12 for explaining the definition of the center point C of the face surface 16 and the face center line CL. FIG. It is a front view explaining the speed distribution of the face surface. It is a front view which shows the example of the speed distribution of a face surface. (A) is a front view for explaining a change in the speed distribution of the face surface due to the ratio of the rolling component when the rolling component is large, and (B) is a speed distribution of the face surface according to the ratio of the rolling component when the rolling component is medium. FIG. 6C is a front view for explaining a change in the speed distribution of the face surface according to the ratio of the rolling component when the rolling component is small. (A), (B) is a figure explaining the maximum initial speed point Pv in the case of hitting the ball 4 with the baseball bat 2. (A), (B) is a figure explaining the maximum initial velocity point Pv when hitting the golf ball 6 with the golf club head 12. (A) is a schematic diagram showing the movement of the golf club head 12 when the face rotation is small, and (B) is a schematic diagram showing the movement of the golf club head 12 when the face rotation is large. It is explanatory drawing which shows the speed distribution of the face surface 12 in case the face rotation FR is 200 rpm. It is explanatory drawing which shows the speed distribution of the face surface 12 in case the face rotation FR is 400 rpm. It is explanatory drawing which shows the speed distribution of the face surface 12 in case the face rotation FR is 800 rpm. FIG. 6 is an explanatory diagram when the center of gravity point G is set so that the maximum initial speed point Pv is arranged on the center point of the face surface 16 in accordance with the face rotation FR. It is explanatory drawing which shows that the maximum initial speed point Pv moves by face rotation FR. It is explanatory drawing which shows the result of having actually measured the face rotation FR when swinging the golf club from which a count differs by several golf players. It is explanatory drawing which shows distribution of face rotation FR when many golfers swing a golf club. It is a block diagram which shows the structure of the computer 30 which comprises a selection apparatus. It is a functional block diagram which shows the structure of a selection apparatus. It is a flowchart which shows the selection operation | movement of the golf club using a selection apparatus. It is a figure which shows the experimental result in case the face rotation FR is 200 rpm. It is a figure which shows the experimental result in case the face rotation FR is 400 rpm. It is a figure which shows the experimental result in case the face rotation FR is 800 rpm. It is explanatory drawing of the gravity center height FGH and the loft angle (alpha). It is a figure explaining the conditions of simulation. It is a figure which shows the simulation result of the gravity center height FGH corresponding to a count and loft angle (alpha). It is a functional block diagram which shows the structure of a design apparatus. It is a flowchart which shows the design operation | movement of the golf club using a design apparatus. (A) The side view of the golf club head 12 explaining the area | region of the face center line CL, (B) The front view of the golf club head 12 explaining the area | region of the face center line CL.

(First embodiment)
Hereinafter, an embodiment according to a golf club selection method of the present invention will be described with reference to the drawings.

First, the golf club used as the object of the selection method of this invention is illustrated.
As shown in FIG. 1, the golf club 10 includes a golf club head 12 and a shaft 14.
In this example, the case where the golf club head 12 is a wood type will be described. However, the golf club head 12 may be an iron type or a utility and is not limited.
The golf club head 12 includes a head body having a metal hollow structure having a face surface 16 for hitting a golf ball and a crown portion 18 and a sole portion 20 connected to the face surface 16 as outer shells.
The metal material of the head body is preferably a high strength low specific gravity metal such as a titanium alloy or an aluminum alloy.
Further, the crown portion 18 is provided with a hosel 22 connected to the shaft at a position close to the heel 26 on the face surface 16 side. Reference numeral 24 denotes tow.

A center of gravity point G and a face center line CL are defined on the face surface 16.
The center-of-gravity point G is a point obtained by projecting the position of the center of gravity of the golf club head 12 perpendicularly to the face surface 16.
The face center line CL refers to a straight line that passes through the center in the toe-heel direction of a region defined as a golf ball hitting region of the face surface 16 and extends in a direction orthogonal to the toe-heel direction.
In other words, the face center line CL refers to a straight line that passes through the center point that is the geometric center of the face surface 16 and extends in a direction perpendicular to the toe-heel direction.
As a method for defining the center point of the face surface 16 and the face center line CL, various conventionally known defining methods as described below can be adopted.

First, a case where the boundary between the face surface 16 and another golf club head 12 is clear, in other words, a case where the periphery of the face surface 16 is specified by a ridge line will be described. In this case, the face surface 16 is clearly defined.
2 to 5 are explanatory views showing an example of a method for defining the center point C of the face surface 16 and the face center line CL.
(1) First, as shown in FIG. 2, the golf club head 12 is placed on a horizontal ground so that the lie angle and the face angle become prescribed values. The state of the golf club head 12 at this time is set as a reference state. Note that the set values of the lie angle and the hook angle are values described in, for example, a product catalog.

(2) Next, a temporary center point c0 in the direction connecting the crown portion 18 and the sole portion 20 is obtained.
That is, as shown in FIG. 2, a perpendicular line f0 that intersects with the approximate center point of a line parallel to the ground connecting the toe 24 and the heel 26 (hereinafter referred to as a horizontal line) is drawn.
The midpoint of the point a0 where the perpendicular f0 intersects the upper edge of the face surface 16 and the midpoint of the point b0 where the perpendicular f0 intersects the lower edge of the face surface 16 is defined as a temporary center point c0.

(3) Next, as shown in FIG. 3, a horizontal line g0 passing through the temporary center point c0 is drawn.
(4) Next, as shown in FIG. 4, the d0 point where the horizontal line g0 and the edge on the toe 24 side of the face surface 16 intersect, and the e0 point where the horizontal line g0 and the edge on the heel 26 side of the face surface 16 intersect. The midpoint is defined as a temporary center point c1.
(5) Next, as shown in FIG. 5, a perpendicular line f1 passing through the temporary center point c1 is drawn, and the perpendicular line f1 and the upper edge of the face surface 16 intersect with each other, and the perpendicular line f1 and the lower edge of the face surface 16 The midpoint of the b1 point where the two intersect is defined as the temporary center point c2.
Here, if the temporary center points c 1 and c 2 coincide with each other, the point is defined as the center point C of the face surface 16.
If the temporary center points c1 and c2 do not match, the procedures (2) to (5) are repeated.
Since the face surface 16 has a curved surface, the length of the horizontal line g0 and the lengths of the vertical lines f0 and f1 when obtaining the midpoint of the horizontal line g0 and the midpoints of the vertical lines f0 and f1 are the curved surfaces of the face surface 16. The length along the line shall be used.
The face center line CL is defined by a straight line that passes through the center point C and extends in a direction orthogonal to the toe-heel direction.

  Next, the definition of the center point C and the face center line CL when the periphery of the face surface 16 and the other golf club head 12 are connected by a curved surface and the face surface 16 cannot be clearly defined will be described. .

As shown in FIG. 6, the golf club head 12 is hollow, the symbol G0 indicates the position of the center of gravity of the golf club head 12, and the symbol Lp is a straight line that connects the center of gravity position G0 and the center of gravity G. Lp is a perpendicular of the face surface 16 passing through the gravity center position G0.
Here, as shown in FIG. 7, a large number of planes H1, H2, H3,..., Hn including a straight line Lp connecting the gravity center position G0 and the gravity center point G are considered.
In the cross section when the golf club head 12 is broken along the planes H1, H2, H3,..., Hn, the curvature radius r0 of the outer surface of the golf club head 12 is measured as shown in FIG.
When measuring the curvature radius r0, it is assumed that there are no face lines, punch marks, or the like on the face surface 16.
The curvature radius r0 is continuously measured from the center point C of the face surface 16 outward (upward and downward in FIG. 8).
Then, in the measurement, a portion where the radius of curvature r0 is initially equal to or smaller than a predetermined value is defined as an outline I representing the periphery of the face surface 16. The predetermined value is, for example, 200 mm.
A region surrounded by the contour line I determined based on a large number of planes H1, H2, H3,..., Hn is defined as a face surface 16 as shown in FIGS.
Next, as shown in FIG. 9, the golf club head 12 is placed on a horizontal ground so that the lie angle and the face angle become predetermined values.
The straight line LT passes through the toe side point PT of the face surface 16 and extends in the vertical direction.
The straight line LH passes through the heel side point PH of the face surface 16 and extends in the vertical direction.
The straight line LC is parallel to the straight line LT and the straight line LH. The distance between the straight line LC and the straight line LT is equal to the distance between the straight line LC and the straight line LH.
The symbol Pu indicates the upper point of the face surface 16, and the symbol Pd is the lower point of the face surface 16. The upper point Pu and the lower point Pd are both intersections of the straight line LC and the contour line I.
The center point C is defined by the midpoint of the line segment connecting the upper point Pu and the lower point Pd.
The face center line CL is a straight line that passes through the center point C and extends in a direction orthogonal to the toe-heel direction, and the straight line LC becomes the face center line CL.

Next, the velocity distribution of the face surface 16 will be described.
The speed distribution of the face surface 16 means the distribution of the speed of the face surface 16 immediately before hitting when a golfer hits a golf ball with the golf club 10.
The speed distribution is mainly determined from a component depending on the length of the shaft 14 and a component due to rolling of the golf club head 12 (rotation around the shaft 14).

As shown in FIG. 10, the component depending on the length of the former shaft 14 is maximized at a point A where the perpendicular of the extension line L of the central axis of the shaft 14 contacts the sole portion 20 of the golf club head 12.
The latter component depending on the rolling of the golf club head 12 is maximized at a point B (the end portion on the toe 24 side of the golf club head 12) farthest from the extension line L of the central axis of the shaft 14.
Therefore, as shown in FIG. 11, the speed of the face surface 16 is distributed so as to gradually increase from the upper part a on the heel 26 side to the lower part g on the toe 24 side.
In FIG. 11, a contour line v is shown for each speed of 0.5 m / s.

  The ratio between the component depending on the length of the shaft 14 and the component depending on the rolling of the golf club head 12 varies depending on the suitability of each golfer. When the component depending on the rolling is large, FIG. As shown in A), the slope of the contour line v increases, and the width between adjacent contour lines v decreases. When the component that depends on the rolling becomes smaller and the component that depends on the length of the shaft 14 becomes larger, as shown in FIG. 12B and FIG. The width between the contour lines v is increased.

In the present invention, the rolling of the golf club head 12 is measured as the face rotation FR. Hereinafter, the rolling is referred to as the face rotation FR.
The face rotation FR is a displacement amount per unit time that the face surface 16 is displaced around the shaft 14 immediately before the golf club head 12 hits the golf ball. In this embodiment, the unit of face rotation FR is the number of revolutions per minute (rpm), but any unit is arbitrary.

Next, the fact that the position of the highest initial speed point on the face surface 16 changes due to the face rotation FR will be described.
First, a case where a ball 4 is hit with a baseball bat 2 will be described as an example with reference to FIGS. 13A and 13B.
A center point G is defined as a point obtained by vertically projecting the center of gravity of the bat 2 onto the surface of the bat 2.
As shown in FIG. 13A, when the bat 2 is moved in parallel, when the ball 4 is hit at the center of gravity G, the flight distance of the ball 4 is maximized. In other words, the maximum initial speed point Pv that maximizes the initial speed of the ball 4 coincides with the gravity center point G.
As shown in FIG. 13B, when the bat 2 is swung (rotated), the ball hits on the tip side of the bat 2 from the center of gravity G rather than hits at the center of gravity G of the bat 2. The flight distance of 4 becomes longer.
The reason for this is as follows.
Since the bat swing is a rotational motion, the velocity distribution of the bat 2 at the moment of collision between the bat 2 and the ball 4 is faster toward the tip side than the location of the center of gravity G.
From the relationship between the collision speed and the collision efficiency, the highest initial speed point Pv, which is the position on the bat 2 where the hitting ball speed is highest, moves to the tip side where the collision speed is faster than the gravity center point G.

As shown in FIGS. 14 (A) and 14 (B), as with the bat 2, the swing of the golf club is also a rotational motion, and therefore the face surface 16 at the moment of collision between the golf club head 12 and the golf ball 6. The velocity distribution is faster toward the tip side than the center of gravity point G.
Therefore, the maximum initial velocity point Pv on the face surface 16 moves to the tip side where the velocity distribution of the face surface 16 is faster than the gravity center point G.

In addition, the velocity distribution on the face surface 16 of the golf club head 12 is also affected by the above-described face rotation FR.
FIG. 15A is a schematic diagram showing the movement of the golf club head 12 when the face rotation FR is small, and FIG. 15B is a schematic diagram showing the movement of the golf club head 12 when the face rotation FR is large.
In the figure, reference numerals w1 and w2 indicate two indexes provided on the golf club head 12. A symbol w3 indicates a straight line passing through the indicators w1 and w2. The symbol θ represents the rotation angle (angular velocity) of the straight line w3 per unit time when the golf club head 12 performs face rotation FR, and the rotation angle θ corresponds to the face rotation FR of the golf club head 12.

FIGS. 16, 17 and 18 are explanatory diagrams showing the speed distribution, the barycentric point P, and the straight line M when the rotations are 200 rpm, 400 rpm, and 800 rpm, respectively.
The horizontal axis indicates the coordinate axis (X axis) on the face surface 16 in the toe-heel direction, the left side is the toe, and the right side is the heel.
The vertical axis represents the coordinate axis (Y-axis) on the face surface 16 in the crown portion-sole portion direction, the upper side being the crown portion and the lower side being the sole portion.
In the figure, reference symbol Vf indicates the velocity distribution (m / sec) of the face surface 16.
In this example, the vertical axis coincides with the face center line CL, and therefore, the horizontal axis is a straight line orthogonal to the face center line CL.
That is, two points where the contour of the area defined as the area hitting the golf ball of the face surface 16 and the face center line CL intersect are the two ends of the face center line CL, and the midpoint of the face center line CL is the face surface 16. The center point of.
More specifically, the horizontal direction from the toe side to the heel side of the face surface 16 of the golf club head 12 with the golf club head 12 set according to the lie angle is the X direction, and the vertical upward direction is the Y direction. .
Further, the intersection (origin) of the horizontal axis and the vertical axis is (0, 0) as the coordinates of the center point of the face surface 16 and the center point of the matching face surface 16 defined below.

As shown in FIGS. 16, 17, and 18, the smaller the face rotation FR of the golf club head 12 (the slower the rotation), the wider the interval between contour lines of the velocity distribution of the face surface 16.
Further, the larger the face rotation FR of the golf club head 12 (the faster the rotation), the narrower the interval between the contour lines v of the velocity distribution of the face surface 16.
16, 17, and 18, the straight line M indicates a straight line that passes through the center point of the face surface 16 and is orthogonal to the contour line v.
An angle φ formed by the straight line M and the X axis (a straight line orthogonal to the face center line CL) indicates the degree of inclination of the contour line v with the horizontal axis.
That is, the smaller the face rotation FR, the larger the angle φ (the inclination of the contour line v becomes smaller), and the larger the face rotation FR, the smaller the angle φ (the inclination of the contour line v becomes larger).

When a golfer swings a golf club and hits a golf ball with the face surface 16, when the distribution of the hit points on the face surface 16 is examined, the hit points are distributed more at the center point of the face surface 16, and the distribution is more away from the center point. Tend to decrease.
Further, the variation in the hit point distribution in the crown-sole direction tends to be larger than the hit point variation in the toe heel direction.
From these results, it can be said that the hit point distribution is highest in the face center line CL and decreases as the distance from the face center line in the toe-heel direction increases.
Therefore, if the maximum initial speed point Pv is arranged on the face center line CL, a large flight distance of the hit ball can be secured.
As described above, it is known that the maximum initial speed point Pv moves from the center of gravity G under the influence of the face rotation FR.
Therefore, the center-of-gravity point G may be set according to the face rotation FR so that the maximum initial speed point Pv is arranged on the face center line CL, more preferably on the center point of the face surface 16. It will be.

FIG. 19 is an explanatory diagram when the center of gravity point G is set so that the maximum initial speed point Pv is arranged on the center point of the face surface 16 in accordance with the face rotation FR.
FIG. 19 illustrates a case where the face rotation FR is 200 rpm, 400 rpm, and 800 rpm.
The smaller the face rotation FR, the shorter the distance from the center point of the face surface 16 to the center of gravity G, and the greater the angle formed by the X direction (horizontal axis) and the straight line connecting the center point and the center of gravity G.
The larger the face rotation FR, the longer the distance from the center point of the face surface 16 to the center of gravity G, and the smaller the angle formed between the X direction and the straight line connecting the center point and the center of gravity G.
That is, as shown in FIG. 20, the maximum initial speed point Pv moves from the center of gravity G along the straight line M to the side where the speed distribution is fast. Therefore, the angle formed by the straight line M connecting the X direction with the center point and the center of gravity G is equal to the angle φ described above.

From the above, the following can be said if the premise that the face rotation FR is substantially constant regardless of the golf club number is the same for the same golfer.
If the face rotation FR of a golfer can be specified, the position of the center of gravity G necessary for the highest initial speed point Pv to be arranged on the face center line CL or the center point of the face surface 16 can be specified. If a golf club head (golf club) having a center of gravity G is selected, it is possible to provide a golf club that improves the flight distance of the hit ball for the golfer.

Hereinafter, the premise that the face rotation FR is substantially constant regardless of the golf club number will be described for the same golfer described above.
FIG. 21 is an explanatory view showing the results of actual measurement of face rotation FR when swinging golf clubs having different counts by a plurality of golfers.
The horizontal axis indicates the golf club number, and the vertical axis indicates the face rotation FR (rpm).
There are 10 golfers A1 to A10 as test subjects.
As the golf clubs, No. 1 and No. 3 (fairway wood) were used as wood-type golf clubs, and No. 3 to No. 9 as iron-type golf clubs and a total of 10 pitching wedges were used.
As shown in FIG. 21, it was found that the variation of the face rotation FR in the same golfer was within ± 50 rpm.
From this result, it is considered that the premise that the face rotation FR is substantially constant regardless of the golf club number is the same golfer.

FIG. 22 is an explanatory diagram showing the distribution of the face rotation FR when a large number of golfers swing the golf club.
The horizontal axis represents face rotation FR (rpm), and the vertical axis represents the ratio (%) to the total number of people.
The face rotation FR is divided in the following range.
The face rotation FR on the horizontal axis and its range are shown below.
100 rpm: 0 to 200 rpm 200 rpm: 200 to 300 rpm 300 rpm: 300 to 400 rpm 400 rpm: 400 to 500 rpm 500 rpm: 500 to 600 rpm 600 rpm: 600 to 700 rpm 700 rpm: 700 to 800 rpm 800 rpm: 800 rpm A person.
The minimum value of the face rotation FR was 209 rpm, the maximum value was 804 rpm, and the average value was 426 rpm.
From FIG. 22, it was found that the range of the face rotation FR is about 200 to 800 rpm.
Note that the measurement of the face rotation FR in FIGS. 21 and 22 was performed by a measuring device that measures the three-dimensional behavior of the golf club head.
As such a behavior measuring device, for example, as disclosed in Japanese Patent Laid-Open No. 2005-34619, the displacement of a plurality of markers provided on a golf club head is continuously photographed by a camera, and the three-dimensional coordinates thereof are taken. In other words, the three-dimensional behavior of the golf club head is measured by processing the time series data of the above with a computer.
Further, the face rotation FR can be measured by the following apparatus.
For example, as shown in FIGS. 15 (A) and 15 (B), by continuously capturing the displacement of two indices w1 and w2 provided on the golf club head with a camera and processing the time-series data with a computer, The face rotation FR can be obtained. Alternatively, the two indices w1 and w2 shown in FIGS. 15A and 15B are configured by reflection markers, and the positions of these two reflection markers are acquired as time-series data by a two-dimensional line sensor. The face rotation FR can be obtained by processing the data with a computer.
As such a device, for example, as disclosed in Japanese Patent Application Laid-Open No. 2009-18043, the difference between the heel side speed Sh and the toe side speed St of the golf club head is δ, and the head speed is H. In this case, an apparatus (Japanese Patent Laid-Open No. 2009-18043) for obtaining the rolling ratio R defined by the ratio δ / H can be used.
The sensor for detecting the behavior of the golf club head is not limited to an optical sensor such as a camera or a line sensor. A magnetic sensor is attached to the grip portion of the golf club, and the movement trajectory and direction of the grip end are time-series data. The face rotation FR may be obtained by obtaining the above and processing these time-series data with a computer. (For example, Japanese Patent No. 3624761)
As described above, as a device for measuring the face rotation FR of the golf club head, conventionally known measuring devices for measuring the behavior of various golf club heads can be used.

In the present invention, the position of the center of gravity G necessary for the highest initial speed point to be located on the face center line CL is determined based on the measurement result of the face rotation FR, and a golf club is selected based on the center of gravity point G. Is.
In the present embodiment, a selection device for selecting a golf club is constituted by a computer.
FIG. 23 is a block diagram showing a configuration of the computer 30 constituting the selection device.
The computer 30 includes a CPU 32, a ROM 34, a RAM 36, a hard disk device 38, a disk device 40, a keyboard 42, a mouse 44, a display 46, a printer 48, an input / output interface 50, etc. connected via an interface circuit (not shown) and a bus line. have.
The ROM 34 stores a control program and the like, and the RAM 36 provides a working area.

  The hard disk device 38 stores a dedicated calculation program for selecting a golf club having a center of gravity G necessary for the highest initial speed point to be located on the face center line CL based on the face rotation FR.

The disk device 40 records and / or reproduces data on a recording medium such as a CD or a DVD.
The keyboard 42 and the mouse 44 receive an operation input by the operator.
The display 46 displays and outputs data, and the printer 48 prints and outputs data. The display 46 and the printer 48 output data.
The input / output interface 50 exchanges data with an external device.

As shown in FIG. 24, the selection device includes a center-of-gravity point calculation unit 30A and a golf club selection unit 30B.
Each of these means is realized by the computer 30 executing the calculation program.

The center-of-gravity point calculation means 30A includes a correlation map 3002 that indicates the correlation between the face rotation FR, the position of the highest initial speed point Pv, and the position of the center of gravity point G.
The correlation map 3002 is configured by the following procedure, for example.
1) A golf club 10 including a golf head club 12 whose position of the center of gravity G is known is prepared.
2) Swing the golf club 10 with a face rotation FR set to a certain value by a swing robot, hit the golf ball with a plurality of hit points set over the entire face surface 16, and measure the initial velocity at each hit point; The hit point with the highest initial speed is defined as the highest initial speed point Pv.
Such measurement is repeatedly performed by changing the value of the face rotation FR.
3) As a result, the correlation between the face rotation FR, the position of the maximum initial speed point Pv, and the position of the center of gravity G is obtained.
From this correlation, a correlation map 3002 is generated that represents the correlation indicating the relationship between the face rotation FR and the position of the center of gravity G when the condition that the position of the maximum initial speed point Pv is located on the face center line CL is satisfied. To do.
Therefore, the center-of-gravity point calculation unit 30A calculates (specifies) the position of the center-of-gravity point G from the correlation map 3002 based on the value of the face rotation FR.

  In the present embodiment, the correlation map 3002 divides the face rotation FR into two or more regions according to the magnitude of the value.

When the face rotation FR is divided into two or more regions according to the magnitude of the value, the position of the center of gravity G is within 6 mm from the face center line CL.
When the distance from the face center line CL to the center of gravity G is the separation distance, the separation distance corresponding to the region with the larger face rotation FR is larger than the separation distance corresponding to the region with the smaller face rotation FR. is there.
If the position of the center of gravity G is within a range of 6 mm or less from the face center line CL toward the heel, the position of the center of gravity G is out of the above range as shown in Experimental Examples 1 to 32 in FIGS. It is more advantageous in securing the flight distance of the hit ball than in the case of.
This is because if the position of the center of gravity G is within 6 mm from the face center line CL, it is advantageous to bring the position of the highest initial speed point Pv closer to the face center line CL or its vicinity.

The case where the face rotation FR is divided into three areas of a small area, a medium area, and a large area is exemplified as follows.
The first threshold value of the face rotation FR is set in advance within a range of 400 rpm ± 50 rpm, and the second threshold value is set within a range of 600 rpm ± 50 rpm.
A region where the face rotation FR is less than the first threshold is a small region, a region where the first threshold is less than the second threshold is a middle region, and a region where the face rotation FR is greater than the second threshold is a large region. Is divided into three regions.
The position of the center of gravity G corresponding to the small region is set to be 0 mm or more and less than 2 mm closer to the heel from the face center line.
The position of the barycentric point G corresponding to the middle region is 2 mm or more and less than 4 mm closer to the heel from the face center line.
The position of the center of gravity G corresponding to the large region is set to be 4 mm or more and 6 mm or less near the heel from the face center line.
In an experimental example to be described later, the first threshold value is 400 rpm and the second threshold value is 600 rpm. Experimental examples 1 to 11 are small areas, experimental examples 12 to 22 are middle areas, and experimental examples 23 to 32 are large areas. .
When the position of the center of gravity G is within the above-defined range, as shown in FIGS. 26, 27, and 28, the flying distance of the hit ball is larger than when the position of the center of gravity G is outside the above range. It becomes more advantageous in securing.
This is because the position of the center of gravity point G is made different depending on the small area, middle area, and large area of the face rotation FR, thereby bringing the maximum initial speed point Pv closer to the face center line CL or its vicinity. This is because it is more advantageous.

In the present embodiment, the case where the face rotation FR is divided into three regions and the center of gravity G is obtained corresponding to each region has been described. However, even if the division of the face rotation FR and the center of gravity G is further subdivided. Good.
For example, the area may be divided into four or more. However, if the area is subdivided unnecessarily, many actual measurement results are required to create the correlation map 3002, which is disadvantageous in reducing costs. Further, as will be described in an experimental example to be described later, even if the number of regions is three, it is sufficient for securing the flight distance of the hit ball.
Further, the face rotation FR may be divided into two regions, a small region and a large region. In this case, the position of the center of gravity G corresponding to the small area is 0 mm or more and less than 3 mm near the heel from the face center line, and the position of the center of gravity G corresponding to the large area is 3 mm or more and 6 mm or less near the heel from the face center line. do it.

The golf club selection means 30B selects the golf club 10 corresponding to the calculated position of the center of gravity G from a plurality of golf clubs 10 prepared in advance.
In other words, the golf club selection means 30B includes, as a database, the positions of the centroid points G of the plurality of golf clubs 10 that can be selected, and the golfer from the database based on the positions of the centroid points G calculated by the centroid point calculation means 30A. A golf club 10 suitable for the face rotation FR is selected.

The angle φ formed by the X direction and the straight line connecting the highest barycentric point Pv and the barycentric point G is exemplified as follows.
The face rotation FR is divided into two or more regions according to the magnitude of the value, the maximum initial speed point Pv on the face center line CL is arbitrarily determined, and the face surface 16 has a defined loft angle. Thus, the center of gravity height FGH from the center of gravity G to the horizontal plane in the state of being arranged on the horizontal plane is 17 mm or more and 23 mm or less.
When the horizontal direction from the toe side to the heel side of the face surface 16 is the X direction, the angle between the X direction and the straight line connecting the maximum initial speed point Pv and the center of gravity point G is an angle φ. The angle φ2 determined corresponding to the center of gravity G calculated corresponding to the region where the face rotation FR is smaller than the angle φ1 determined corresponding to the center of gravity G calculated corresponding to the larger region. It ’s big.
When the center of gravity height FGH is within a range of 17 mm or more and 23 mm or less, when hitting a ball placed on the ground, the center of gravity of the golf club head 12 and the center of gravity of the ball are close to each other, and the initial velocity of the ball is further improved. Is advantageous.
When φ1 <φ2, the straight line connecting the maximum initial speed point Pv and the center of gravity G approaches the straight line M perpendicular to the contour line v indicating the face speed distribution, as shown in FIGS. It is advantageous in improving the effect effectively.

In addition, when the position of the face rotation FR and the center of gravity point G is divided into three regions of a small region, a middle region, and a large region, the angle φ is exemplified as follows.
When the center of gravity height FGH is 17 mm or more and 23 mm or less, and the face rotation FR is a small region, the angle φ is 37 ° or more and 54 ° or less, and when the face rotation FR is a middle region, the angle φ is 20 ° or more and 37. If the face rotation FR is a large region, the angle φ is 5 ° to less than 20 °.
When the center of gravity height FGH is within a range of 17 mm or more and 23 mm or less, when hitting a ball placed on the ground, the center of gravity of the golf club head 12 and the center of gravity of the ball are close to each other, and the initial velocity of the ball is further improved. Is advantageous.
When the angle φ is in the above range, the straight line connecting the maximum initial speed point Pv and the gravity center point G approaches the straight line M orthogonal to the contour line v indicating the face speed distribution, as shown in FIGS. This is advantageous in improving the speed effectively.
Note that when the position of the face rotation FR and the center of gravity G is divided into two regions of a small region and a large region, the angle φ is exemplified as follows.
When the face rotation FR is a small region, the angle φ is 29 ° to 54 °, and when the face rotation FR is a large region, the angle φ is 5 ° to less than 29 °.

The definition of the loft angle and the center of gravity height FGH of the golf club head 12 is exemplified as follows.
That is, as shown in FIG. 29, as the loft angle α of the golf club head 12 increases, the center of gravity height FGH gradually decreases and the center of gravity height FGH and the loft when the loft angle α is the maximum value are increased. The difference from the center of gravity height FGH when the angle α is the minimum value is preferably 2 mm or more and 3 mm or less.
The relationship between the loft angle α and the center of gravity height FGH will be described.
As shown in FIG. 30, the optimal center of gravity height FGH when a golf ball at a position 4 mm above the ground is impacted by the golf club head 12 (iron club) with the sole portion 20 in contact with the ground is simulated. Sought by.
In this case, the optimum center-of-gravity height FGH is a value at which the initial ball speed becomes maximum, in other words, a value at which the golf ball can be impacted by a sweet spot on the face surface 16.
FIG. 31 shows the simulation result.
The horizontal axis indicates the iron club number and loft angle α, and the vertical axis indicates the center of gravity height FGH.
Further, the head speed (H / S) of the golf club head 12 was set to three stages of 35 m / sec, 40 m / sec, and 45 m / sec.
As apparent from FIG. 31, the difference between the center of gravity height FGH when the loft angle α is the maximum value and the center of gravity height FGH when the loft angle α is the minimum value at any head speed is 2.5 mm. Was within.
Therefore, if the difference between the center of gravity height FGH when the loft angle α is the maximum value and the center of gravity height FGH when the loft angle α is the minimum value is 2 mm or more and 3 mm or less, it can be said that there is no problem in use. .

The golf club selection operation using the selection device will be described with reference to the flowchart of FIG.
A case where the golf club 10 is selected in a facility such as a golf shop or a driving range will be described as an example.
The face rotation FR when the golfer swings the golf club 10 is measured by the behavior measurement device (step S10: face rotation FR measurement step). In this case, the service provider of the facility provides the golf club 10 for measurement to the golfer. Alternatively, the golfer may use the golf club 10 brought by himself.

Next, the measurement result of the face rotation FR is input through the input / output interface 50 of the computer 30 shown in FIG.
Thereby, the center-of-gravity point calculation means 30A calculates the position of the center-of-gravity point G from the correlation map 3002 based on the face rotation FR (step S12: center-of-gravity point calculation step).

In addition, as shown in FIGS. 34A and 34B, the location of the face center line CL that hits the golf ball in the gravity center calculation step is on a horizontal plane so that the face surface 16 has a defined loft angle α. It is an area from the lower end of the face surface 16 to a location located at a height of 40 mm in the vertical direction in the arranged state.
This is because the ball is not hit in a region exceeding the height of 40 mm in the vertical direction from the lower end of the face surface 16.

Next, the golf club selection unit 30B selects the golf club 10 based on the position of the center of gravity G (step S14: selection step).
Specifically, the selected golf club 10 is displayed on the display 46 of the computer 30 or printed out by the printer 48.
Based on the selection result of the golf club 10 output in this way, the service provider of the facility provides the golf club 10 most suitable for the golfer or provides information (manufacturer, model number, etc.) of the golf club 10.

As described above, according to the present embodiment, the golf ball 10 is measured by the face rotation FR of the golf club 10 swung by the golfer, and the golf ball is detected by the face center line CL of the face surface 16 that is displaced by the measured face rotation FR. The position of the center of gravity G necessary for the initial speed when the ball is hit to the maximum initial speed is calculated as the position of the center of gravity G corresponding to the measured face rotation FR, and the calculated position of the center of gravity G Based on this, the golf club 10 suitable for the golfer's face rotation FR is selected.
Therefore, it is possible to select a golf club that is advantageous in improving the flight distance of the hit ball in accordance with the golfer's swing.

In the present embodiment, the case where one golf club 10 is selected has been described. However, the present invention is naturally applicable to a golf club set including a plurality of golf clubs 10.
For example, the selected golf club is a plurality of golf clubs constituting an iron golf club set.
In this case, the plurality of golf clubs include one or more golf clubs having a loft angle of less than 28 degrees, one golf club having a loft angle of 28 degrees or more and less than 40 degrees, and one golf club having a loft angle of 40 degrees or more. Includes more than books. Specifically, the plurality of golf clubs are golf clubs having a loft angle of less than 28 degrees, for example, among 4th (4th iron), 5th (5th iron), 6th (6th iron) One or more golf clubs with a loft angle of 28 degrees or more and less than 40 degrees, one or more of 7th (7th iron), 8th (8th iron), 9th (9th iron), loft angle As a golf club of 40 degrees or more, one or more of PW (pitching wedge), AW (approach wedge), and SW (sand wedge) are included.
Further, in the plurality of golf clubs, as the loft angle α increases, the center of gravity height FGH gradually decreases, and the center of gravity height FGH and the loft angle α when the loft angle α is the maximum value are minimum values. The difference from the center of gravity height FGH in some cases is 2 mm or more and 3 mm or less.
When an iron golf club set is constituted by the plurality of golf clubs 10 selected as described above, the following effects are exhibited.
By using a plurality of golf clubs selected by the selection method of the present invention, the golfer hits a target hit point, that is, a hit point at the optimum center-of-gravity height position FGH on the face center line CL and for each loft angle α. It is advantageous in achieving the maximum initial speed.
That is, since the parameter that most affects the flight distance is the initial speed, using a plurality of golf clubs selected by the selection method of the present invention is advantageous in obtaining the intended flight distance for each golf club number. Therefore, it is advantageous in achieving a score increase.

(Experimental example)
Next, experimental examples will be described with reference to FIGS. 26, 27, and 28. FIG.
As a sample, a golf club 10 (iron club) having a golf club head 12 in which the position of the center of gravity G is changed is created, and each golf club 10 is swung using a swing robot. The maximum flight distance when hitting was measured.
The experimental conditions are as follows.
1) There are three types of face rotation FR: 200 rpm, 400 rpm, and 800 rpm, and the face rotation FR is divided into the above-described three regions, the small region, the medium region, and the large region.
2) The position of the center of gravity G is expressed as a numerical value of + (positive) on the heel side and − (negative) on the toe side, with the center point of the face surface 16 being the origin (0, 0).
3) The maximum flight distance is indicated by an index with the maximum flight distance being 100 in each of the small, medium, and large areas of the face rotation FR.
4) Golf club number 5
5) As for the number of hits, trial hits were made until the number of hits at the center line CL was approximately 5 or more, and the data was an average value of 5 balls.
6) In Experimental Examples 9, 10, 11, 20, 21, 22, 30, 31, and 32, measurement was performed as a golf club set. In this case, the golf clubs are numbered 6, 6, 7, 8, 9, and PW, and the six golf clubs were tested by the same method as above to measure the maximum flight distance. The average value was obtained for each golf club set.

Here, the position of the center of gravity G corresponding to each of the small region, the medium region, and the large region of the face rotation FR and the range in which the angle φ is defined will be shown again.
(Small area of face rotation FR)
Position of the center of gravity G: From the face center line CL toward the heel 0 mm or more and less than 2 mm Angle φ: 37 ° or more and 54 ° or less (middle area of the face rotation FR)
Position of the center of gravity G: 2 mm or more and less than 4 mm closer to the heel from the face center line CL Angle φ: 20 ° or more and less than 37 ° (large area of the face rotation FR)
Position of the center of gravity G: 4 mm or more and 6 mm or less near the heel from the face center line CL Angle φ: 5 ° or more and less than 20 ° Further, the center of gravity height FGH in each of the small region, medium region, and large region of the face rotation FR is Each region is 17 mm or more and 23 mm or less.
In the case of a club set, the difference between the center of gravity height FGH when the loft angle α is the maximum value and the center of gravity height FGH when the loft angle α is the minimum value is 2 mm or more and 3 mm or less.

With reference to FIG. 26, Experimental Examples 1 to 11 in which the face rotation FR is 200 rpm (small region) will be described.
In Experimental Example 1, the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range.
In Experimental Examples 2 to 4, the position of the center of gravity point G deviates from the specified range, and the center of gravity height FGH and the angle φ are within the specified range.
In Experimental Example 5, the position of the barycentric point G is within the specified range, the barycentric height FGH is below the specified range, and the angle φ is within the specified range.
In Experimental Example 6, the position of the center of gravity point G is within the specified range, the center of gravity height FGH is greater than the specified range, and the angle φ is within the specified range.
In Experimental Example 7, the position of the center of gravity point G and the center of gravity height FGH are within the specified range, and the angle φ is below the specified range.
In Experimental Example 8, the position of the barycentric point G and the barycentric height FGH are within the specified range, and the angle φ exceeds the specified range.
Experimental Example 9 is a club set, which is within a range in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are defined, and within the range in which the difference in the center of gravity height FGH is defined.
Experimental example 10 is a club set in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range, and the difference in the center of gravity height FGH is below the specified range.
Experimental example 11 is a club set in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range, and the difference in the center of gravity height FGH exceeds the specified range.
As is clear from FIG. 26, when the face rotation FR is 200 rpm (small region), the maximum flight distance of Experimental Example 1 in which the position of the center of gravity G, the height of the center of gravity FGH, and the angle φ are within the specified range. The biggest.
In Experimental Examples 2 to 8, in which any one of the position of the center of gravity G, the height of the center of gravity FGH, and the angle φ is outside the specified range, the maximum flight distance is lower than that of Experimental Example 1.
In the case of the club sets of Experimental Examples 9, 10, and 11, the maximum flight distance of Experimental Example 9 that is within the range in which the difference in the center of gravity height FGH is specified is the largest, and the difference in the center of gravity height FGH is specified. The maximum flight distances of Experimental Examples 10 and 11 that are out of the range are lower than those of Experimental Example 9.

Next, experimental examples 12 to 22 in which the face rotation FR is 400 rpm (middle region) will be described with reference to FIG.
In Experimental Example 12, the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range.
In Experimental Examples 13 to 15, the position of the center of gravity point G deviates from the specified range, and the center of gravity height FGH and the angle φ are within the specified range.
In Experimental Example 16, the position of the centroid point G is within the specified range, the centroid height FGH is below the specified range, and the angle φ is within the specified range.
In Experimental Example 17, the position of the centroid point G is within a specified range, the centroid height FGH is greater than the specified range, and the angle φ is within the specified range.
In Experimental Example 18, the position of the centroid point G and the centroid height FGH are within the specified range, and the angle φ is below the specified range.
In Experimental Example 19, the position of the center of gravity G and the center of gravity height FGH are within the specified range, and the angle φ exceeds the specified range.
Experimental example 20 is a club set, which is within a range in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are defined, and within the range in which the difference in the center of gravity height FGH is defined.
Experimental example 21 is a club set in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range, and the difference in the center of gravity height FGH is below the specified range.
Experimental Example 22 is a club set in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range, and the difference in the center of gravity height FGH exceeds the specified range.
As is clear from FIG. 27, when the face rotation FR is 400 rpm (middle region), the maximum flight distance of Experimental Example 12 in which the position of the center of gravity G, the height of the center of gravity FGH, and the angle φ are within the specified range. The biggest.
In Experimental Examples 13 to 19 in which any one of the position of the center of gravity G, the center of gravity height FGH, and the angle φ is outside the specified range, the maximum flight distance is lower than that of Experimental Example 12.
In the case of the club sets of Experimental Examples 20, 21, and 22, the maximum flight distance of Experimental Example 20, which is within the range in which the difference in the center of gravity height FGH is defined, is the largest, and the difference in the center of gravity height FGH is defined. The maximum flight distances of Experimental Examples 21 and 22 that are out of the range are lower than those of Experimental Example 20.

Next, experimental examples 23 to 32 in which the face rotation FR is 800 rpm (large region) will be described with reference to FIG.
In Experimental Example 23, the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range.
In Experimental Examples 24 and 25, the position of the center of gravity G deviates from the specified range, and the center of gravity height FGH and the angle φ are within the specified range.
In Experimental Example 26, the position of the centroid point G is within the specified range, the centroid height FGH is below the specified range, and the angle φ is within the specified range.
In Experimental Example 27, the position of the center of gravity G is within a specified range, the center of gravity height FGH exceeds the specified range, and the angle φ is within the specified range.
In Experimental Example 28, the position of the center of gravity point G and the center of gravity height FGH are within the specified range, and the angle φ is below the specified range.
In Experimental Example 29, the position of the centroid point G and the centroid height FGH are within the specified range, and the angle φ exceeds the specified range.
Experimental example 30 is a club set, which is in a range in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are defined, and in the range in which the difference in the center of gravity height FGH is defined.
Experimental example 31 is a club set in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range, and the difference in the center of gravity height FGH is below the specified range.
Experimental example 32 is a club set in which the position of the center of gravity G, the center of gravity height FGH, and the angle φ are within the specified range, and the difference in the center of gravity height FGH exceeds the specified range.
As is clear from FIG. 28, when the face rotation FR is 800 rpm (large area), the maximum flight distance of Experimental Example 23 in which the position of the center of gravity G, the height of the center of gravity FGH, and the angle φ are within the specified range. The biggest.
In Experimental Examples 24 to 29 in which any one of the position of the center of gravity G, the center of gravity height FGH, and the angle φ is outside the specified range, the maximum flight distance is lower than that in Experimental Example 23.
Further, in the case of the club sets of Experimental Examples 30, 31, and 32, the maximum flight distance of Experimental Example 30, which is within the range in which the difference in the center of gravity height FGH is defined, is the largest, and the difference in the center of gravity height FGH is defined. The maximum flight distance of Experimental Examples 31 and 32 that are out of the range is lower than that of Experimental Example 30.

  As is clear from the above experimental results, when the position of the center of gravity G, the height of the center of gravity FGH, and the angle φ are within the ranges defined in accordance with the face rotation FR, the maximum when hit with the face center line CL This is advantageous for securing a large flight distance.

(Second Embodiment)
Next, a method for designing a golf club of the present invention will be described.
In the first embodiment, the position of the center of gravity G necessary for the highest initial speed point Pv to be positioned on the face center line CL is determined based on the measurement result of the face rotation FR, and based on the center of gravity G. A golf club was selected.
On the other hand, in the second embodiment, the face rotation FR is set in advance, and the center of gravity necessary for the highest initial speed point Pv to be positioned on the face center line CL based on the set face rotation FR. The position of G is calculated, and the golf club head is designed based on the center of gravity G.
In the following embodiments, the same parts and members as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted or simply performed.

In the present embodiment, a design device for designing a golf club is constituted by a computer.
Referring to FIG. 23, the computer 30 is configured in the same manner as in the first embodiment.
However, the hard disk device 38 stores a dedicated calculation program for designing a golf club head having a center of gravity G necessary for the highest initial speed point to be located on the face center line CL based on the face rotation FR. This is different from the first embodiment.

As shown in FIG. 32, the design apparatus includes a center-of-gravity point calculation unit 30C and a design unit 30D.
Each of these means is realized by the computer 30 executing the calculation program.

The center-of-gravity point calculation means 30C includes a correlation map 3010 indicating the correlation between the face rotation FR, the position of the highest initial speed point Pv, and the position of the center of gravity point G.
This correlation map 3010 is configured in the same manner as the correlation map 3002 in the first embodiment.
When the face rotation FR is input, the center-of-gravity point calculation unit 30C receives the face rotation FR, and calculates (specifies) the position of the center of gravity point G from the correlation map 3010 based on the value of the face rotation FR.

The design means 30 </ b> D determines design variables for the golf club head 12 based on the calculated position of the center of gravity G.
The design means 30 </ b> D includes a database having various conventionally known design programs used for designing the golf club head 12 and design variables of the golf club head 12.
Examples of such design variables include center of gravity distance, center of gravity height, center of gravity depth, and moment of inertia.

Golf club design using the design apparatus will be described with reference to the flowchart of FIG.
First, when the design operator operates the keyboard 42, mouse 44, etc., the face rotation FR is input to the computer 30, or the face rotation FR is input as data from the input / output interface 50 to the computer 30 (step S20).
The center-of-gravity point calculation means 30C receives the input face rotation FR and sets it as a face rotation FR for use in design (step S22: face rotation FR setting step).
Next, the center-of-gravity point calculation unit 30C calculates the position of the center-of-gravity point G from the correlation map 3010 based on the set face rotation FR (step S24: center-of-gravity point calculation step).
Next, the design means 30D determines the design variable of the golf club head 12 based on the calculated position of the center of gravity G (step S26: design step).
Next, the computer 30 displays the determined design variable on the display 46 of the computer 30 or prints it out by the printer 48 (step S28).

As described above, according to the present embodiment, the center of gravity necessary for the initial speed when the golf ball is hit at the face center line CL of the face surface 16 that is displaced by the set face rotation FR to be the maximum initial speed. The position of the point G is calculated as the position of the center of gravity G corresponding to the set face rotation FR, and the design variable of the golf club head 12 is determined based on the calculated position of the center of gravity G.
Therefore, it is possible to design a golf club that is advantageous in improving the flight distance of the hit ball in accordance with the golfer's swing.
Moreover, although the golf club 10 has been described in the present embodiment, the present invention can of course be applied to a golf club set including a plurality of golf clubs 10.

  10: Golf club, 12: Golf club head, 16: Face surface, CL: Face center line, G: Center of gravity, FR: Face rotation.

Claims (9)

A golf club selection method for measuring a behavior of a golf club head immediately before the golf club head of a golf club swung by a golfer hits a golf ball and selecting a golf club based on the measurement result,
The amount of displacement per unit time that the face surface is displaced around the shaft axis of the golf club immediately before the golf club head hits the golf ball is referred to as face rotation.
A straight line extending through the center in the toe-heel direction of a region defined as a region hitting the golf ball in the face surface and extending in a direction perpendicular to the toe-heel direction is a face center line,
When a point obtained by projecting the center of gravity position of the golf club head perpendicularly to the face surface is a center of gravity point,
A face rotation measuring step for measuring a face rotation of a golf club swung by a golfer;
A center-of-gravity point calculating step for calculating a position of a center of gravity point necessary for the initial speed when the golf ball is hit at the face center line of the face surface displaced by the measured face rotation to be a maximum initial speed;
A selection step of selecting a golf club suitable for the golfer's face rotation based on the calculated position of the center of gravity;
A method for selecting a golf club, comprising: Dividing the face rotation into two or more regions according to the magnitude of the value,
The position of the barycentric point is within 6 mm closer to the heel from the face center line,
When the distance from the face center line to the center of gravity is the separation distance,
The separation distance corresponding to the region with the larger face rotation is larger than the separation distance corresponding to the region with the smaller face rotation.
The golf club selection method according to claim 1, wherein: The first threshold value of the face rotation is set in advance within a range of 400 rpm ± 50 rpm, and the second threshold value is set within a range of 600 rpm ± 50 rpm,
A region where the face rotation is less than the first threshold is a small region, a region where the face rotation is greater than the first threshold and less than the second threshold is a middle region, and a region where the face rotation is greater than the second threshold is a large region. And dividing the face rotation into three regions,
The position of the center of gravity corresponding to the small region is 0 mm or more and less than 2 mm closer to the heel from the face center line,
The position of the center of gravity corresponding to the middle region is 2 mm or more and less than 4 mm closer to the heel from the face center line,
The position of the center of gravity corresponding to the large region is 4 mm or more and 6 mm or less near the heel from the face center line.
The golf club selection method according to claim 1, wherein: The face rotation is divided into two or more regions according to the magnitude of the value,
A maximum initial velocity point on the face center line is arbitrarily determined, and the center of gravity height from the center of gravity to the horizontal plane is 17 mm in a state where the face surface is arranged on a horizontal plane so as to have a specified loft angle. More than 23 mm,
When the horizontal direction from the toe side to the heel side of the face surface is the X direction,
When the angle formed by the X direction and the straight line connecting the highest initial speed point and the center of gravity is an angle φ,
Corresponding to the position of the center of gravity specified corresponding to the region having a smaller face rotation than the angle φ determined corresponding to the position of the center of gravity specified corresponding to the region having the larger face rotation. The angle φ determined by the
The golf club selection method according to claim 1, wherein: A maximum initial velocity point on the face center line is arbitrarily determined, and the center of gravity height from the center of gravity to the horizontal plane is 17 mm in a state where the face surface is arranged on a horizontal plane so as to have a specified loft angle. More than 23 mm,
When the horizontal direction from the toe side to the heel side of the face surface is the X direction,
When the angle formed by the X direction and the straight line connecting the highest initial speed point and the center of gravity is an angle φ,
When the face rotation is a small region, the angle φ is 37 ° to 54 °, when the face rotation is a middle region, 20 ° to less than 37 °, and when the face rotation is a large region, the angle φ Is less than 5 ° -20 °,
The golf club selection method according to claim 3, wherein: As the loft angle of the golf club head increases, the center of gravity height gradually decreases, and the center of gravity when the loft angle is the maximum value and the center of gravity when the loft angle is the minimum value. The difference from the height is 2 mm or more and 3 mm or less,
6. The method for selecting a golf club according to claim 4, wherein the golf club is selected. The selected golf club is a plurality of golf clubs constituting an iron golf club set,
The plurality of golf clubs include one or more golf clubs having a loft angle of less than 28 degrees, one or more golf clubs having a loft angle of 28 degrees or more and less than 40 degrees, and one golf club having a loft angle of 40 degrees or more. Including more than
The golf club selection method according to claim 6. The location of the face center line that hits the golf ball in the gravity center calculating step is such that the golf club head is placed on a horizontal plane so that the face surface has a prescribed loft angle, and the lower end of the face surface Is a region from a position located at a height of 40 mm in the vertical direction,
The method for selecting a golf club according to claim 1, wherein the golf club is selected. The amount of displacement per unit time that the face surface is displaced around the shaft axis of the golf club immediately before the golf club head strikes the golf ball is referred to as face rotation.
A straight line extending through a center in the toe-heel direction of a region defined as a region hitting the golf ball in the face surface and extending in a direction perpendicular to the toe-heel direction is a face center line,
When the position of the center of gravity of the golf club head projected perpendicularly to the face surface is the center of gravity point,
A face rotation setting step in which the face rotation is set;
The position of the center of gravity required for the initial speed when the golf ball is hit at the face center line of the face surface that is displaced by the set face rotation to be the maximum initial speed corresponds to the set face rotation. A center-of-gravity point calculation step for calculating the position of the center of gravity point;
A design step of determining a design variable of the golf club head based on the calculated position of the center of gravity;
A method for designing a golf club, comprising:

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