JP2013192756A - Golf club head, golf club and trajectory calculation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect, when calculating a trajectory of a ball hit using a golf club head capable of changing the balance of weight, a physical quantity used for the calculation using a sensor which is easily attached and detached to/from a head body.SOLUTION: A sole part 23 of a golf club head 10 is provided with holes 25 and 42. A detachable weight member 30 is attached to the hole 25, and a detachable detection member 40 is attached to the hole 26. In the detection member 40, an angular velocity sensor and an acceleration sensor are provided. When a ball collides with a face surface, the golf club head 10 is accelerated in a certain direction by impact force received from the ball, and is rotated in a certain direction with an axis passing through the centroid as the center. A trajectory calculating device calculates the trajectory of the ball by finding out the acceleration and the rotation on the basis of an angular velocity and an acceleration respectively detected by both sensors.

Description

  The present invention relates to a technique for calculating a trajectory of a ball that has collided with a golf club head.

  There is a technique for detecting the movement of a golf club head using a sensor attached to the golf club head. Patent Document 1 describes a technique for obtaining the head speed and face surface inclination based on measurement data from an acceleration detector built in the golf club head.

Japanese Unexamined Patent Publication No. 64-11573

  By the way, some golf club heads can be detachably attached with various weights. By changing the weight of the weight to be attached, the balance of the weight of the golf club head can be changed and the position of the center of gravity can be adjusted. is there. This is intended to change the movement of the golf club head during the swing by changing the weight balance, and to bring the ball trajectory closer to what the user wants. For example, this is called fitting. . In this fitting, for example, using the technique of Patent Document 1, the movement of the golf club head is obtained from the physical quantity (that is, acceleration) detected by the sensor (that is, acceleration detector) attached to the golf club head, and the result is obtained. It is conceivable to calculate an expected ball trajectory.

  However, in a golf club head to which such a sensor is attached, the sensor may fail due to an impact at the time of hitting. In that case, in the technique of Patent Document 1, since the sensor is built in the golf club head, it takes time and effort to replace the failed sensor. Also, in golf games and competitive golf, the use of a golf club head with an electrically operated device such as an acceleration detector is not permitted. I can't play with it.

  Therefore, the present invention provides a physical quantity used for calculation using a sensor that can be easily attached to and detached from the head body when calculating the trajectory of a ball hit using a golf club head capable of changing the weight balance. The purpose is to detect.

In order to solve the above problems, the present invention provides a head body and a sensor for detecting a physical quantity representing the movement of the head body, and outputs data indicating the detected physical quantity to a transmission means for transmitting data. There is provided a golf club head comprising: a sensor that includes a weight that is detachably attached to the head body.
In the present invention, the weight may have adjusting means for adjusting the orientation of the sensor.

  In addition, the present invention includes the above-described golf club head, a shaft, a grip attached to the shaft, and a transmission unit that transmits data output from the sensor, the transmission unit including the shaft A golf club is provided, wherein the golf club is provided at a portion to which the grip is attached.

Further, the present invention provides a golf club comprising the above-described golf club head, shaft, grip attached to the shaft, and transmission means for transmitting data output from the sensor, or the above-described golf club and the transmission means. And receiving means for receiving data indicating a physical quantity detected by the sensor when the golf club is swung and the golf club head collides with a ball, and the receiving means receives the data. A trajectory calculation system comprising: a calculation device that calculates the trajectory of the ball based on a physical quantity indicated by the data obtained.
In the present invention, the head body has a face surface on the front side, and the sensor detects an angular velocity centered on an axis that forms a predetermined angle with the front-rear direction of the head body as the physical quantity, and the calculation device May calculate a vertical spin amount or a horizontal spin amount of the ball from the angular velocity detected by the sensor, and calculate the trajectory using the calculated spin amount.

  According to the present invention, when calculating the trajectory of a ball hit using a golf club head capable of changing the weight balance, the physical quantity used for the calculation using a sensor that can be easily attached to and detached from the head body. Can be detected.

It is a figure which shows the external appearance of the track | orbit calculation system 1 in embodiment. It is a figure which shows the external appearance of a golf club head. It is a figure which shows the mode at the moment when a golf club head collides with a ball. It is a figure which shows the cross section of a head main body. It is a figure which shows the external appearance of a detection member. It is a figure which shows the cross section of the grip part of a golf club. It is a figure which shows the structure of the hardware with which a track | orbit calculation apparatus is provided. It is a figure for demonstrating the magnitude | size of an impact force. It is a figure for demonstrating the amount of rotations of a golf club head. It is a figure for demonstrating the amount of rotations of a golf club head. It is a figure for demonstrating a collision direction and direction of a face surface. It is a figure for demonstrating a collision direction and direction of a face surface.

[Embodiment]
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating an appearance of a trajectory calculation system 1 in the embodiment. The track calculation system 1 includes a golf club 2 and a track calculation device 3. The golf club 2 includes a golf club head 10, a shaft 11, and a grip 12. A golf club head 10 is attached to one end of the shaft 11, and a grip 12 is attached to the other end. The trajectory calculation device 3 is a desktop personal computer, and when the user swings the golf club 2 and hits the ball (golf ball), the trajectory of the ball is determined from the movement of the golf club head 10 that collides with the ball. Is a device for calculating. The trajectory calculated by the trajectory calculation device 3 is used as a reference when a user purchases a golf club, for example, or displays the result of hitting a ball in a game that is played indoors while reflecting the scenery of the golf course on the screen. It is used for the purpose of doing.

  FIG. 2 is a view showing the appearance of the golf club head 10. The golf club head 10 includes a face portion 21, a crown portion 22, a sole portion 23 and a hosel portion 24 that form a head body 20, a weight member 30, and a detection member 40. FIG. 2A shows the golf club head 10 viewed from the face portion 21 side. The face portion 21 is a portion of the golf club head 10 that collides with the ball and transmits the kinetic energy of the golf club 2 to the ball. Of the face portion 21, a surface on which the ball collides, that is, a surface exposed to the outside of the golf club head 10 is referred to as a face surface. The face portion 21 is connected to the crown portion 22 on the side facing the sky when the user holds the golf club 2, and is connected to the sole portion 23 on the side facing the ground. In the golf club head 10, the side on which the crown portion 22 is located is referred to as the crown side, and the side on which the sole portion 23 is located is referred to as the sole side. A direction from the crown side toward the sole side (direction indicated by an arrow A1 in the figure) is referred to as a crown / sole direction. The hosel portion 24 is a portion of the golf club head 10 to which a shaft is attached. The crown part 22 is connected to the hosel part 24. Hereinafter, in the golf club head 10, the side on which the hosel portion 24 is located is referred to as a heel side, and the opposite side is referred to as a toe side. A direction from the toe side toward the heel side (direction indicated by an arrow A2 in the figure) is referred to as a toe / heel direction.

  FIG. 2B shows the golf club head 10 viewed from the heel side, and FIG. 2C shows the golf club head 10 viewed from the sole side. In the golf club head 10, when viewed from the heel side, the side on which the face portion 21 is located is referred to as a front side, and the opposite side is referred to as a rear side. A direction from the front side toward the rear side (direction indicated by an arrow A3 in the drawing) is referred to as a front-rear direction. On the rear side of the face portion 21, the crown portion 22 and the sole portion 23 are connected to each other. A weight member 30 is attached to a position of the sole portion 23 that is closer to the face portion 21 than the center in the front-rear direction and closer to the heel side than the center in the toe / heel direction. Hereinafter, this position is referred to as a “first attachment position”. The weight member 30 is detachable and can be detached from the first attachment position. Another weight member having a weight different from that of the weight member 30 is also attached to the first attachment position. When the weight of the weight member attached to the first attachment position changes, the weight balance between the first attachment position and other positions in the golf club head 10 changes, and the golf club head 10 moves during the swing. Changes.

  For example, by attaching a weight member heavier than the weight member 30 to the first attachment position, the weight balance of the first attachment position with respect to other positions increases, and the position of the center of gravity of the golf club head 10 is the first attachment position. Move in the direction of the position. Since the center of gravity of the golf club head 10 is approximately at the center in the toe-heel direction and the center in the front-rear direction, the movement of the golf club head 10 approaches the axis of the shaft 11. This makes it easier for the golf club head 10 to rotate about the axis of the shaft 11 than when the weight member 30 is attached to the first attachment position. Thus, the weight member functions as a weight that changes the balance of the weight.

  FIG. 3 is a diagram illustrating a state in which the golf club head 10 collides with the ball when the user swings the golf club 2. In FIG. 3, a flying ball direction A4 indicating a direction in which the user wants to fly the ball is indicated by an arrow. Further, in FIG. 3, in order to make the orientation of the golf club head 10 at this moment easy to understand, a two-dot chain line perpendicular to the flying ball direction A4 passes through a position where the golf club head 10 and the ball collide. Show. In FIG. 3A, the portion of the face portion 21 that collides with the ball is perpendicular to the flying ball direction A4. On the other hand, in FIG. 3B, the toe side of the golf club head 10 is delayed from the heel side, that is, a so-called face surface is open. In FIG. The toe side precedes the heel side, that is, the so-called face surface is closed. When the face surface is open, slicing is likely to occur, and when the face surface is closed, hooks are likely to occur.

  When the user swings the golf club 2 in the same way, the face surface becomes easier to close as the golf club head 10 easily rotates around the axis of the shaft 11, and the face surface becomes more difficult to rotate. It becomes easy to open. For example, if the user tends to open the face surface, increasing the weight of the weight member attached to the first mounting position makes it easier for the face surface to be closed, making it difficult to slice. can do. In this manner, fitting a golf ball close to a desired one for a user by changing the characteristics of the golf club such as the above-described head movement without changing the swing is called fitting.

  Returning to FIG. A detection member 40 is attached to a position of the sole portion 23 near the center in the toe / heel direction and the end on the rear side. Hereinafter, this position is referred to as a “second attachment position”. The detection member 40 has an angular velocity sensor and an acceleration sensor inside. The results detected by these sensors are used when the trajectory calculation device 3 described above calculates the trajectory of the ball. The detection member 40 can be attached to and detached from the sole portion 23. That is, the detection member 40 can be removed from the second attachment position. The weight member 30 can be attached to the second attachment position from which the detection member 40 has been removed. Conversely, the detection member 40 can be attached to the first attachment position from which the weight member 30 has been removed. In short, the weight member 30 and the detection member 40 are both attached to both the first attachment position and the second attachment position.

  For example, when the user performs the above fitting at a golf driving range or a golf equipment store, the detection member 40 is attached to the second attachment position, and when playing at the golf course, the weight member 30 is attached to the second attachment position. It is used such as attaching. The detection member 40 is formed to have the same weight as the weight member 30. For this reason, even if the detection member 40 and the weight member 30 are replaced, the weight balance between the second attachment position and the other position does not change. As described above, the detection member also functions as a weight that changes the above-described weight balance, like the weight member.

Next, details of the detection member 40 will be described.
FIG. 4 is a view showing a cross section of the head main body 20 as viewed in the direction of arrows IV-IV in FIG. Arrow IV-IV indicates a direction from the center of the head body 20 in the toe-heel direction toward the heel side. In FIG. 4, the detection member 40 shows an appearance, not a cross-section, for easy viewing. 4A shows the head main body 20 to which the weight member 30 and the detection member 40 are attached. In FIG. 4B, the weight member 30 and the detection member 40 are removed from the head main body 20. However, it is shown. As shown in these drawings, the head main body 20 is hollow, and a hole 25 is provided at the first attachment position of the sole portion 23 and a hole 26 is provided at the second attachment position. Inside the holes 25 and 42, female threads (not shown) are cut. The weight member 30 and the detection member 40 are in the form of bolts, and can be attached to the first and second attachment positions by screwing the male threaded portions into the holes 25 and 42, respectively. ing.

  As described above, the shaft 11 is inserted inside the hosel portion 24. The shaft 11 has a hollow portion 13 inside. A wiring 48 is arranged from the hollow portion 13 to the detection member 40. The wiring 48 is connected to the detection member 40. As shown in FIG. 4B, the detection member 40 and the wiring 48 are connected in a state where the detection member 40 is detached from the head body 20, and then the detection member 40 is attached to the second attachment position. The state shown in FIG.

  FIG. 5 is a diagram illustrating an appearance of the detection member 40. FIG. 5A shows an enlarged view of the detection member 40 in FIG. The detection member 40 includes a bolt head portion 41, a bolt screw portion 42, an angular velocity sensor 43, an acceleration sensor 44, and a direction adjustment member 45. In FIG.5 (b), the detection member 40 seen from the bolt head 41 side is shown. The bolt head 41 is formed in a disk shape (doughnut shape) with a hole in the center, and is connected to the bolt screw portion 42. The bolt head portion 41 is provided with two holes 46 on the side opposite to the side connected to the bolt screw portion 42, and can be rotated by an instrument in which a protrusion is inserted into these holes 46. ing. The bolt head is not limited to this shape, and may be, for example, a hexagonal column shape (so-called hexagon bolt head) or a butterfly wing shape (so-called butterfly bolt head). In short, the bolt head only needs to have a shape that can be rotated by the user.

  The bolt screw portion 42 is formed in the shape of a hollow cylinder, and a male screw (not shown) is cut on the outer peripheral surface. When the bolt head 41 is rotated, the bolt screw portion 42 is also rotated about the axis and screwed into the hole 25. The hollow space of the bolt screw portion 42 is connected to the central hole of the bolt head portion 41. In this space, an angular velocity sensor 43 and an acceleration sensor 44 are provided.

  The angular velocity sensor 43 is a sensor that detects angular velocities about the three axes. The three axes are the X axis, the Y axis, and the Z axis shown in FIG. The Z axis is an axis that passes through the center P <b> 1 of the angular velocity sensor 43 and extends along the axis of the bolt screw portion 42. The X axis and the Y axis are orthogonal to the Z axis and orthogonal to each other at the center P1. The acceleration sensor 44 is a sensor that detects the degree of acceleration (acceleration) of the center P2 of the sensor in three directions. These three directions are the same as the directions in which the X axis, the Y axis, and the Z axis respectively extend (referred to as the X axis direction, the Y axis direction, and the Z axis direction, respectively). The angular velocity sensor 43 and the acceleration sensor 44 are connected to each other. A wiring 48 is connected to the angular velocity sensor 43 and the acceleration sensor 44. The wiring 48 is drawn out of the bolt screw portion 42 from a hole 47 provided in the bolt screw portion 42. Data indicating the angular velocity detected by the angular velocity sensor 43 and data indicating the acceleration detected by the acceleration sensor 44 are output via the wiring 48.

  The direction adjusting member 45 is provided such that one end thereof is connected to the acceleration sensor 44 and the other end is exposed to the outside from the central hole of the bolt head 41. The other end is formed in a disk shape and is supported by the bolt head 41 so as to rotate in the circumferential direction. A straight groove is formed on the surface of the direction adjusting member 45 exposed from the bolt head 41. When the direction adjusting member 45 is rotated by applying a flathead screwdriver or the like to the groove, both the acceleration sensor 44 connected to the direction adjusting member 45 and the angular velocity sensor 43 connected to the acceleration sensor 44 are rotated. ing. The user rotates the direction adjusting member 45 to adjust the direction of the X axis and the Y axis among the three axes whose angular velocities are detected by the angular velocity sensor 43, and the acceleration sensor 44 detects the acceleration. Among the directions, the directions in the X-axis direction and the Y-axis direction can be adjusted. Thus, the direction adjusting member 45 functions as an adjusting unit that adjusts the directions of the angular velocity sensor 43 and the acceleration sensor 44. In the present embodiment, it is assumed that the orientation of the angular velocity sensor 43 is adjusted so that the Y axis is directed in the toe / heel direction. That is, the direction of the acceleration sensor 44 is also adjusted so that the Y-axis direction is in the toe-heel direction.

  FIG. 6 is a cross-sectional view of a portion of the golf club 2 to which the grip 12 is attached. A communication device 50 is provided in the hollow portion 13 inside the shaft 11 located inside the grip 12. The communication device 50 includes a power supply unit that supplies power using a battery or the like, and a communication unit that operates with the power supplied from the power supply unit. For example, the communication unit performs wireless communication according to a standard such as Bluetooth (registered trademark). 4 is connected to the communication device 50, and data is output from the angular velocity sensor 43 and the acceleration sensor 44, respectively. The communication device 50 wirelessly transmits these data output from both sensors by the operation of the communication unit described above. As described above, the communication device 50 functions as a transmission unit that transmits data indicating the results (angular velocity and acceleration) detected by these sensors. The communication device 50 is provided in a portion of the shaft 11 to which the grip 12 is attached (hereinafter referred to as “grip portion”).

  The grip portion is the portion of the golf club 2 that is farthest from the golf club head 10 and is covered with the grip 12 so that the impact force received by the golf club head 10 is least transmitted. is there. Further, in the grip portion, the shaft 11 is not bent or twisted during the swing. That is, the communication device 50 is provided at a place where the golf club 2 is most difficult to break. For example, when the communication device 50 is provided inside the head body 20, the balance of the weight of the golf club head 10 is affected. In the golf club 2, since the communication device 50 is provided in the grip portion, such an influence is prevented. These data transmitted by the communication device 50 are received by the trajectory calculation device 3 shown in FIG.

  FIG. 7 is a diagram illustrating a hardware configuration included in the trajectory calculation apparatus 3. The trajectory calculation device 3 includes a control unit 31, a storage unit 32, a communication unit 33, an operation unit 34, a display unit 35, and a power supply unit 36. The control unit 31 includes an arithmetic device including a CPU (Central Processing Unit) and a memory. The arithmetic unit of the control unit 31 executes programs stored in the memory and the storage unit 32 to control each unit of the trajectory calculation device 3 and process data. The storage unit 32 includes a storage device such as an HDD (Hard Disk Drive), and stores the above-described programs, image data indicating images, and the like. The operation unit 34 is an operator such as a keyboard or a mouse, and supplies operation data representing the operation content to the control unit 31 in accordance with a user operation. The display unit 35 includes a liquid crystal display screen and a liquid crystal driving circuit, and displays an image indicated by image data supplied from the control unit 31. The power supply unit 36 has a plug and a power line connected to an outlet (not shown), and supplies the power acquired via the plug and the power line to each unit included in the trajectory calculation device 3.

  The communication unit 33 performs wireless communication using, for example, the Bluetooth standard, and wirelessly communicates with the communication device 50 described above. The communication unit 33 functions as a receiving unit that receives data transmitted by the communication device 50. The data received by the communication unit 33 is, for example, data indicating the angular velocity and acceleration detected by the sensors described above when the golf club 2 is swung and the golf club head 10 collides with the ball. The communication unit 33 supplies data transmitted from the communication device 50 to the control unit 31. Note that data exchange by wireless communication as described above may be performed using a memory such as a micro SD (Secure Digital). In this case, for example, a micro SD is provided inside the shaft 11 instead of the communication device 50, and data output from each sensor described above is stored in the micro SD. The micro SD is taken out after the golf club is swung. The trajectory calculation apparatus includes means for reading the micro SD instead of the communication unit 33, and data is exchanged by the means reading data from the micro SD taken out after the swing.

  By providing the above hardware, the trajectory calculation device 3 functions as a calculation device that calculates the trajectory of the ball that has collided with the golf club head 10 based on the angular velocity and acceleration indicated by the data received by the communication unit 33. The trajectory calculation device 3 calculates the trajectory of the ball based on the initial velocity of the ball, the spin amount, and the launch angle. The initial velocity of the ball refers to the velocity of the ball at the moment when the ball accelerated instantaneously by colliding with the golf club head 10 leaves the golf club head 10. The initial velocity of the ball is a value corresponding to the magnitude of the force (referred to as impact force) received from the golf club head 10 when the ball collides with the golf club head 10. The trajectory calculation device 3 calculates the value of the initial velocity of the ball by obtaining this impact force.

  FIG. 8 is a diagram for explaining the magnitude of the impact force. FIG. 8 shows a change in acceleration in the front-rear direction (the direction from the front side to the rear side shown in FIG. 2) of the golf club head 10 during the period in which the ball is in contact with the head. This acceleration is obtained by summing the components in the front-rear direction of the acceleration in the X-axis direction and the acceleration in the Z-axis direction detected by the acceleration sensor 44. In FIG. 8, the horizontal axis indicates time and the vertical axis indicates acceleration. This acceleration is shown to be a negative value when accelerating in the front-rear direction. The golf club head 10 that has collided with the ball is accelerated in the front-rear direction because it continues to receive force in the front-rear direction from the ball while the ball is in contact with the face surface. In other words, while the golf club head 10 is accelerating in the front-rear direction, the ball is in contact with the face surface. Hereinafter, this period is referred to as a “ball contact period”. In FIG. 8, the ball contact period is indicated by a range B1.

  This ball contact period is obtained as a period during which the golf club head 10 receives a force from the ball. The magnitude of the force that the golf club head 10 receives from the ball during the ball contact period, that is, the impact force, is a value obtained by integrating the magnitude of acceleration during the ball contact period, that is, a predetermined coefficient k1 for the area B2 in FIG. It is calculated by multiplying. The coefficient k1 is determined by the restitution coefficient of the golf club head 10 and the ball. The coefficient k1 can be obtained from, for example, a value obtained by measuring the initial velocity of a ball hit at a different head speed using the golf club 2 by a known method and the size of the area of B2 at that time. By obtaining the coefficient k1 in advance in this way, the trajectory calculation device 3 calculates the acceleration in the front-rear direction from the result detected by the acceleration sensor 44, and the value obtained by multiplying the acceleration by the coefficient k1 Calculated as the initial speed value.

Further, the trajectory calculation device 3 calculates the spin amount of the ball based on the rotation amount of the golf club head 10 around the center of gravity. The amount of spin represents the degree of speed at which the ball rotates, and is calculated, for example, at a revolution per minute (rpm).
9 and 10 are diagrams for explaining the rotation amount of the golf club head 10. FIG. 9 shows an example of a state in which the golf club head 10 colliding with the ball is viewed in the horizontal direction from the toe side. In FIG. 9, for easy understanding, a cross section of the head main body 20, the appearance of the detection member 40 and the ball, and the center of gravity C of the golf club head 10 are shown. FIG. 9A shows a state at the moment when the ball contacts the golf club head 10, and FIG. 9B shows a state at the moment when the ball leaves the golf club head 10.

  In this example, the impact force in the direction and magnitude indicated by the vector D0 shown in FIG. 9A is applied to the golf club head 10 from the ball. Actually, this impact force is given over the ball contact period, but for the convenience of explanation, it is shown in FIG. In this case, the golf club head 10 is moved such that the front side moves to the crown side and the rear side moves to the sole side by the component force represented by the vector D1 in the circumferential direction around the center of gravity C of the impact force. Rotate around the center of gravity C. In this example, as shown in FIG. 9B, the golf club head 10 rotates about the center of gravity C by an angle θ1 until the golf club head 10 finishes receiving impact force from the ball. As described above, the angular velocity sensor 43 is adjusted so that the Y-axis faces the toe-heel direction. For this reason, the angle θ1 is an angle obtained by rotating the golf club head 10 around an axis parallel to the Y axis and passing through the center of gravity C. At this time, as shown in FIG. 9B, the angular velocity sensor 43 is rotated by an angle θ1 about the Y axis. The trajectory calculation device 3 obtains the angle θ1 by integrating the angular velocity around the Y axis during the ball contact period.

  Further, the ball colliding with the golf club head 10 also receives a force D2 for rotating the ball in the direction from the contact point with the face surface toward the crown side due to friction with the face portion 21. This is a phenomenon called the gear effect. The magnitude of the force D2 increases as the angle θ1 increases. The trajectory calculation device 3 calculates a value corresponding to the angle θ1 obtained as described above as the spin amount of the ball around the Y axis (hereinafter referred to as “longitudinal spin amount”). The longitudinal spin rate is the number of rotations per unit time of so-called back spin and top spin. The vertical direction here is the crown / sole direction during the ball contact period, and is generally the direction along the vertical direction. The relationship between the angle θ1 and the amount of spin in the vertical direction depends on the friction coefficient between the ball and the face surface, the elastic modulus of the ball (the contact area between the ball and the face surface varies depending on how much the ball is deformed), and head speed. It depends on such things. This relationship is obtained, for example, by measuring the amount of longitudinal spin by a well-known method when the ball collides with various positions on the face surface at various speeds and the angle θ1 obtained at that time. be able to. By obtaining this relationship in advance, the trajectory calculation device 3 calculates the angle θ1 from the result detected by the angular velocity sensor 43, and calculates a value corresponding to the angle θ1 as the vertical spin amount.

  FIG. 10 shows an example of a golf club head 10 that collides with a ball as viewed from the sole side. 10A shows the moment when the ball collides with the golf club head 10, and FIG. 10B shows the moment when the ball leaves the golf club head 10. The golf club head 10 rotates by an angle θ2 about the center of gravity C with the same phenomenon as in the example of FIG. This angle θ2 represents an angle at which the golf club head 10 is rotated about an axis parallel to the crown / sole direction and passing through the center of gravity C. This axis is generally parallel to the vertical direction when the ball is hit, and is hereinafter referred to as a “vertical axis”. At this time, the angular velocity sensor 43 is also rotated by an angle θ2 about the vertical axis. The trajectory calculation device 3 integrates the angular velocities centered on the X axis and the Z axis during the ball contact period, and calculates the angle θ2 by summing the vertical axis components. Then, the relationship between the angle θ2 and the spin amount of the ball centering on the axis along the crown / sole direction (hereinafter referred to as “lateral spin amount”) is obtained in the same manner as the longitudinal spin amount. The calculation device 3 calculates a value corresponding to the angle θ2 calculated using the result detected by the angular velocity sensor 43 as the lateral spin amount. This lateral spin amount is the number of rotations per unit time of so-called slice spin and hook spin. Here, the lateral direction is the toe-heel direction during the ball contact period, and is generally a direction along the horizontal direction.

Further, the trajectory calculation device 3 determines the launch angle based on the direction in which the golf club head 10 moves during the above-described ball contact period (hereinafter referred to as “collision direction”) and the orientation of the face surface with respect to the collision direction. calculate. This launch angle is represented by an angle formed by the direction in which the ball travels and the collision direction at the moment of leaving the face surface.
FIG. 11 is a diagram for explaining the collision direction and the orientation of the face surface when the golf club head 10 is viewed in the horizontal direction. FIG. 11A shows a vector D3 obtained by combining the vectors representing the integrated values of the accelerations in the three directions detected by the acceleration sensor 44 during the above-described ball contact period as viewed upward in the vertical direction. These pre-combination vectors represent the component forces in three directions of the impact force that the golf club head 10 receives from the ball. That is, the vector D3 represents the direction and magnitude of the golf club head 10 that receives an impact force.

  The direction in which the impact force is applied to the face surface is a direction perpendicular to the face surface unless friction is applied between the face surface and the ball. However, since the friction is actually applied, it is affected by the collision direction. In other words, the collision direction is a direction according to the direction of the vector D3. By obtaining the relationship between the vector D3 and the collision direction in advance, the trajectory calculation device 3 calculates a value corresponding to the vector D3 calculated using the result detected by the acceleration sensor 44 as the collision direction. In FIG. 11A, the collision direction A5, which is an example of the collision direction calculated by the trajectory calculation device 3, is indicated by an arrow. The trajectory calculation device 3 represents the vector D3 and the collision direction A5 in the X-axis, Y-axis, and Z-axis coordinate systems shown in FIG.

  FIG. 11B shows the orientation of the face surface with respect to the collision direction A5. The orientation of the face surface is represented by an angle θ3 of the face surface with respect to a virtual surface E3 perpendicular to the collision direction A5. The face surface forms a gentle curved surface called a bulge, but the trajectory calculation device 3 calculates the angle formed by the tangent plane E1 and the surface E3 at the center of the face surface as θ3. The trajectory calculation device 3 stores in advance an expression that represents the tangent plane E1 in the coordinate system according to the position and orientation where the acceleration sensor 44 is attached.

FIG. 12 is a diagram illustrating a collision direction and a face surface direction when viewed in the vertical direction. In FIG. 12, the vector D3, the collision direction A5, the tangent plane E1, and the plane E3 described above are shown. As shown in this figure, the tangential plane E1 and the plane E3 form an angle θ4 when viewed in the horizontal direction. As described above, the trajectory calculation device 3 calculates θ3 when viewed in the vertical direction and θ4 when viewed in the horizontal direction among the angles formed by the tangent plane E1 and the surface E3. To do. Then, the trajectory calculation device 3 calculates the ball launch angle from the calculated angles θ3 and θ4.
The trajectory calculation device 3 calculates the trajectory of the ball based on the values of the initial velocity, spin amount and launch angle calculated as described above. The trajectory calculation device 3 calculates the trajectory of the ball using a known technique.

  According to the present embodiment, even when the user cannot confirm the trajectory of the hit ball, such as an indoor practice field, the user uses the golf club 2 in which the detection member 40 is attached to the golf club head 10 to play the ball. By hitting, the trajectory of the ball calculated by the trajectory calculation device 3 can be confirmed. Then, by changing the weight of the weight attached to the golf club head 10 according to the confirmed result, the balance of the weight of the golf club head 10 matches the swing of the player as described in FIG. Can be adjusted.

  There is a system for calculating the trajectory of a ball by photographing the hit ball with a camera or detecting the position with a sensor. In such a system, since a camera and a sensor must be installed around the ball, it takes time. For example, in a practice field, there is no place to install these, and there are cases where it cannot be used. According to the golf club head 10 of the present embodiment, since the sensors (the angular velocity sensor 43 and the acceleration sensor 44) used for calculating the trajectory of the ball are attached to the golf club head 10, the above-described trouble is not required. Any place that can hit the ball with the golf club 2 can be used.

  There is a system for detecting angular velocity and acceleration using a sensor built in a golf club head, that is, a sensor mounted inside a hollow. In such a system, the golf club 2 including the golf club head 10 can be used in any place, but if the built-in sensor is broken due to impact at the time of impact, it is replaced. This is difficult compared to the golf club head 10. In the golf club head 10, when a sensor included in the detection member 40 is broken, the detection member 40 may be removed and a replacement detection member 40 may be attached. Since this operation is the same as the operation of removing and attaching the detachable weight, it can be performed more easily than the operation of replacing the aforementioned built-in sensor.

A golf club head to which an electrically operating device such as each sensor of the detection member 40 is attached may be prohibited from being used in a golf game or competitive golf. In such a case, if the golf club head 10 is used, the detection member 40 is removed and the weight member is attached to play, compared to the case where the head incorporating the sensor is used. Furthermore, by making the weight member to be attached have the same weight as the detection member 40, the user can play without changing the balance of the weight adjusted as described above.
As described above, according to the present embodiment, when calculating the trajectory of a ball hit using a golf club head capable of changing the weight balance like the golf club head 10, A physical quantity (angular velocity and acceleration) used for the calculation can be detected using sensors (angular velocity sensor 43 and acceleration sensor 44) that can be easily attached and detached.

[Modification]
The above-described embodiment is merely an example of implementation of the present invention, and may be modified as follows. Moreover, you may implement combining embodiment mentioned above and each modification shown below as needed.

(Modification 1)
In the above-described embodiment, the trajectory calculation device is a desktop personal computer, but may be a laptop computer, a smartphone such as iPhone, or a tablet such as iPad. In short, the trajectory calculation device only needs to be able to execute the process of calculating the trajectory of the ball based on the detection result (angular velocity and acceleration) by the detection member 40 and transmit the result to the user.

(Modification 2)
The trajectory calculation apparatus may convey this result to the user by displaying it as an image, or may convey it by voice. For example, if the amount of spin in the horizontal direction is within a certain range, the sound “Nice shot” is output, and if it is out of the range, the sound “Slice” or “It is hook” is output. . Further, the value of the horizontal spin amount or the vertical spin amount itself may be output by voice. If the trajectory calculation device is a smartphone as described above, the user puts the smartphone in a pocket or the like, listens to the spin amount value by voice while watching the trajectory of the ball after swinging, and The relationship with the spin amount can be recognized.

(Modification 3)
The trajectory calculation device may be composed of a plurality of devices. For example, the trajectory calculation and the result display may be performed by different devices. For example, the communication device 50 transmits the detection result to a server on the Internet, and the server calculates the trajectory of the ball. Then, data indicating the trajectory of the ball calculated by the server is transmitted to the user's smartphone, and the smartphone displays the trajectory indicated by the data. As a result, when the time required to calculate the trajectory on a smartphone is too long for the user, for example, 5 minutes or 10 minutes, the user confirms the trajectory by causing the server to calculate the trajectory with a faster process. You can shorten the time to wait.

(Modification 4)
The trajectory calculation device may calculate the trajectory of the ball by a method different from the method described in the embodiment. For example, the trajectory calculation apparatus calculates the ball contact period using the result detected by the acceleration sensor 44, but may calculate using the result detected by the angular velocity sensor 43. Since the golf club head 10 receives an impact force from the ball during the period from the moment of collision with the ball until the ball leaves, that is, during the ball contact period, the golf club head 10 rotates in a certain direction around the center of gravity. Then, after the ball leaves the golf club head 10, the movement rotating in this direction is settled. Therefore, the absolute value of the result detected by the angular velocity sensor 43 repeatedly increases and decreases like the detection result of acceleration shown in FIG. 8. However, after increasing to the maximum value, it decreases and converges. The trajectory calculation device specifies a range similar to the range B1 shown in FIG. 8 in the detection result by the angular velocity sensor 43 as the ball contact period.

  In addition, for example, in the above-described embodiment, the trajectory calculation apparatus calculates three values of the initial velocity, spin amount, and launch angle of the ball. From the result of calculating one or two of these values, the trajectory of the ball is calculated. Is calculated. In this case, the trajectory calculation device only needs to include a sensor that detects a physical quantity necessary for calculating a value. For example, if only the spin amount is calculated, the trajectory calculation device includes the angular velocity sensor 43 and may not include the acceleration sensor 44. If only the initial velocity is calculated, the trajectory calculation device The acceleration sensor 44 is provided, and the angular velocity sensor 43 may not be provided. In the above-described embodiment, the trajectory calculation apparatus calculates the angular velocity and acceleration by integrating the detection results in the ball contact period, but the maximum value in this period may be calculated as each value. Further, the trajectory calculation apparatus may calculate the trajectory of the ball using a known technique different from the method described above.

(Modification 5)
In the embodiment described above, the number of the axes for detecting the angular velocity is three, but the angular velocity sensor is not limited to this, and may be one, two, or four or more. In any case, the trajectory calculation device decomposes the angular velocity detected by the angular velocity sensor into a component having the crown / sole direction as an axis and a component having the toe / heel direction as an axis, thereby causing the above-described longitudinal spin. The amount and the lateral spin amount can be calculated. That is, the angular velocity sensor only needs to detect an angular velocity centered on an axis that forms a predetermined angle in the front-rear direction of the head body 20. In this case, the trajectory calculation device calculates the longitudinal spin amount and the lateral spin amount from the angular velocity detected by the angular velocity sensor, and calculates the trajectory of the ball using these calculated spin amounts. Note that the trajectory calculation apparatus may calculate only one of the vertical spin amount and the horizontal spin amount, and calculate the trajectory using the calculated spin amount.

(Modification 6)
Although the detection member has the angular velocity sensor 43 and the acceleration sensor 44 in the above-described embodiment, the detection member may have a sensor other than these. For example, the detection member may include a sensor that detects the magnitude (amplitude) of vibration called a vibration sensor, a sensor that detects the magnitude of shock called an impact sensor, and the like. The amplitude and magnitude of impact detected by these sensors are in accordance with the magnitude of the impact force applied to the head body 20, that is, in accordance with the initial velocity of the ball. In this case, as described in the embodiment, the relationship between the amplitude and the magnitude of impact and the initial velocity of the ball is obtained in advance. The trajectory calculation device calculates the initial velocity of the ball from the relationship obtained by the detection results of these sensors and calculates the trajectory of the ball. Each of the sensors described above detects a physical quantity that represents the movement of the head body 20 such as the acceleration, angular velocity, amplitude, and magnitude of impact of the head body 20. Then, the trajectory calculation device calculates the initial velocity, spin amount, and launch angle of the ball from the movement of the head body 20, and calculates the trajectory of the ball. That is, the detection member only needs to have a sensor that detects a physical quantity representing the movement of the head body 20.

(Modification 7)
In the above-described embodiment, the head main body has the first and second attachment positions at which the weight member and the detection member are attached. This position may be, for example, on the toe side of the sole portion or on the sole side of the center of gravity of the head body. This position may be in the crown portion. In short, the weight member and the detection member only need to be detachably attached to the head body. Thus, similarly to the embodiment, when calculating the trajectory of a ball hit using a golf club head capable of changing the weight balance like the golf club head 10, it is easy to attach and detach the head body. A physical quantity used for the calculation can be detected using a simple sensor.

(Modification 8)
In the embodiment described above, the communication device 50 is provided in a portion of the hollow portion 13 of the shaft 11 where the grip 12 is attached, but may be provided in a location other than this. For example, the communication device 50 may be provided in a location other than the portion of the hollow portion 13 to which the grip 12 is attached. Further, the communication device 50 may be provided inside the detection member 40 as long as the size can be accommodated. In this case, there is no need to connect or disconnect the wiring 48, and the convenience for the user can be improved.

(Modification 9)
In the embodiment described above, the orientations of the angular velocity sensor 43 and the acceleration sensor 44 are adjusted so that the Y-axis direction and the Y-axis direction are directed to the toe-heel direction, respectively. The trajectory calculation device 3 can calculate values such as the impact force and the angle θ1 even if these sensors are adjusted so as to face in directions other than the toe-heel direction. For example, in the case of acceleration, the trajectory calculation device 3 calculates the longitudinal component of each detected acceleration if the angles formed by the X-axis direction, the Y-axis direction, and the Z-axis direction with respect to the longitudinal direction are known. In total, the ball contact period and impact force can be calculated as described above. Further, the trajectory calculation device 3 determines the tow from each detected angular velocity if the angle formed by the X axis, the Y axis, and the Z axis with respect to the toe / heel direction and the crown / sole direction is known. The angle θ1 and θ2 can be calculated by calculating the angular velocity component about the heel direction and the angular velocity component about the crown / sole direction (vertical axis in the embodiment). In addition, the trajectory calculation device 3 stores the formulas representing the tangent plane E1 in the coordinate system of the X axis, the Y axis, and the Z axis in advance, so that the angles θ3 and θ4 can be set as in the above-described embodiment. Can be calculated. In addition, by adjusting the direction of the angular velocity sensor 43 using the direction adjusting member 45 as in the embodiment, a value obtained by integrating as it is without calculating the component force from the detected value represents the angle θ1. Become. That is, by using the direction adjusting member 45, the amount of calculation by the trajectory calculation device 3 can be reduced, and the time required for calculating the ball trajectory can be shortened.

DESCRIPTION OF SYMBOLS 1 ... Track calculation system, 2 ... Golf club, 3 ... Track calculation apparatus, 10 ... Golf club head, 11 ... Shaft, 12 ... Grip, 20 ... Head main body, 21 ... Face part, 22 ... Crown part, 23 ... Sole part , 24 ... hosel part, 30 ... weight member, 40 ... detection member, 41 ... bolt head, 42 ... bolt screw part, 43 ... angular velocity sensor, 44 ... acceleration sensor, 45 ... direction adjusting member, 48 ... wiring, 50 ... Communication device 31 ... Control unit 32 ... Storage unit 33 ... Communication unit 34 ... Operation unit 35 ... Display unit 36 ... Power supply unit

Claims (5)

The head body,
A sensor for detecting a physical quantity representing movement of the head body, the sensor having a sensor for outputting data indicating the detected physical quantity to a transmitting means for transmitting data, and detachably attached to the head body A golf club head comprising: a weight that can be used. The golf club head according to claim 2, wherein the weight includes adjusting means for adjusting a direction of the sensor. The golf club head according to claim 1 or 2,
A shaft,
A grip attached to the shaft;
Transmission means for transmitting data output by the sensor,
The golf club according to claim 1, wherein the transmitting means is provided in a portion of the shaft to which the grip is attached. 4. A golf club comprising: the golf club head according to claim 1; a shaft; a grip attached to the shaft; and a transmission means for transmitting data output from the sensor; or the golf club according to claim 3. ,
Receiving data that is data transmitted by the transmitting means, the receiving means receiving data indicating a physical quantity detected by the sensor when the golf club is swung and the golf club head collides with a ball; A trajectory calculation system comprising: a calculation device that calculates a trajectory of the ball based on a physical quantity indicated by data received by the means. The head body has a face surface on the front side,
The sensor detects an angular velocity centered on an axis that forms a predetermined angle with the longitudinal direction of the head body as the physical quantity,
The calculation device calculates a vertical spin amount or a horizontal spin amount of the ball from the angular velocity detected by the sensor, and calculates the trajectory using the calculated spin amount. The trajectory calculation system according to claim 4.

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