JP2019084325A - Golf club head - Google Patents

Abstract

To provide a wood golf club head capable of increasing a carry by disposing a repulsive net composed of a spring wire, at an inner face of a face part for hitting a ball, and capable of suppressing the weight of the club head.SOLUTION: The golf club head includes a face part 2 for hitting a ball 5, and the face part 2 has an elastic plate 3 formed of a metal plate, brought into contact with an inner face thereof. The elastic plate 3 includes a support portion 3b fixed to the inside of a head body 1, and an action portion 3a coming into contact with the inner face of the face part 2. Reinforcement beads BD are continuously formed in the longitudinal direction from the action portion 3a to the support portion 3b. The action portion 3a of the elastic plate 3 is configured to receive elastic deformation of the face part 2 when the ball 5 is hit onto the face part 2, and to repel it by elasticity, along with the face part 2.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a golf club head provided with a face portion for striking a ball on the front surface of the head body, and relates to a golf club head capable of obtaining a great flight distance by a strong striking force.

  As performance required for golf club heads such as drivers and spoons, in particular, it is desired to extend the flight distance of the ball after impact. In order to extend the flight distance of the ball, the face member may be elastically deformed greatly at the time of hitting and the deflection amount may be increased to increase the coefficient of repulsion between the wood head and the ball. This makes it possible to increase the speed of the ball after impact and to effectively extend the flight distance. In order to satisfy such requirements, means adopted conventionally are JP-A-2016-221168 (Patent Document 1), JP-A-2013-202143 (Patent Document 2), and JP-A 2008- As disclosed in the 36050 gazette (patent document 3), it is devised to extend the flight distance by providing a thick portion and a thin portion on the back surface of the face. Further, Japanese Patent Laid-Open No. 2016-158915 (Patent Document 4) discloses that a spring member for pressing the back surface of the face is provided in the head main body. Further, Japanese Patent Laid-Open No. 2015-85069 (Patent Document 5) discloses that pressurized gas is injected into the hollow head body in an airtight state.

JP, 2016-221168, A JP, 2013-202143, A JP, 2008-36050, A JP, 2016-158915, A JP, 2015-85069, A

  Generally, as shown in Patent Documents 1 to 3, the flight distance can be extended by providing a thin portion on the face, and therefore, it is adopted in many hollow golf clubs. However, it is difficult to reduce the thickness of the thin part because a pressure is applied to the face when hitting a ball, and a pressure of more than 1 ton is applied to the face, which makes it difficult to extend the flight distance. It is the present condition to reach. In order to solve this problem, Patent Document 4 proposes a golf club head in which the face is repelled by a coiled spring member, but the weight of the spring member and a member for fixing the same are different. In addition, the weight of the club head is increased, which makes it difficult to adjust the balance, and there is a problem that the expected flight distance can not be extended. In addition, although the hollow golf club head disclosed in Patent Document 5 tries to obtain a repulsive force by the gas injected into the head body, it is difficult to make the head body completely airtight, and the inside with time. As the pressurized gas leaks, there is a problem that the flight distance decreases later even if the flight distance is increased to some extent initially.

  An object of the present invention is to provide a golf club head capable of increasing a flying distance by an elastic plate brought into contact with an inner surface of a face portion that strikes a ball, and further capable of suppressing the weight of the club head. It is to do.

  In order to solve the above problems, the golf club head according to the present invention comprises a face portion for striking a ball, and an elastic plate formed of a metal plate is in contact with the inner surface of the face portion. A support portion fixed to the inside of the head body and an action portion abutting on the inner surface of the face portion are formed, and a reinforcing bead is formed continuously from the action portion to the support portion, the face The present invention is characterized in that the action portion of the elastic plate receives the elastic deformation of the face portion when the ball is hit on the portion and causes the face portion to repel the elasticity by elasticity.

  Further, in the action portion of the elastic plate, a collar portion is formed on both sides of the opening side of the bead formed at the center in the longitudinal direction, and the collar portion of the bead is in contact with the inner surface of the face portion.

  Further, the elastic plate forms a plurality of the action parts, and raises the base sides of the action parts from the support part.

  Furthermore, the elastic plate fixes the support portion to the upper and lower inner surfaces of the head main body, forms the action portion between the upper and lower support portions, and forms the central portion of the action portion on the inner surface of the face portion. You may make it contact | abut.

  Further, the elastic plate comprises an upper set in which the support portion is fixed to the upper inner surface of the head body, and a lower set fixed to the lower inner surface of the head body, and the action portion of each set is the inner surface of the face portion. You may make it contact.

  According to the golf club head of the present invention, since the elastic plate formed of the metal plate is in contact with the inner surface of the face portion which strikes the ball, the face portion is elastically deformed by striking the ball and the elastic plate Since the ball is repelled by the elasticity of the elastic plate, the elastic repulsion of the elastic plate is added to the elastic repulsion of the face portion to increase the flight distance. Furthermore, by forming a long thin bead continuously in the longitudinal direction from the action part of the elastic plate to the support part, the strength of the elastic plate is reinforced four times or more with respect to the flat metal plate, The weight of the elastic plate can be reduced because the thickness of the elastic plate can be reduced to a fraction of a part, and the weight of the club head itself is minimized even if the elastic plate is provided. It becomes possible. Further, by appropriately setting the width, depth, length and position of the groove of the bead formed on the elastic plate, it is possible to obtain an optimum elastic force.

  In addition, since the ridges are formed on both sides of the long thin bead formed in the longitudinal direction on the opening side, the ridges abut against the inner surface of the face portion, thereby damaging the face portion when the ball is hit. Can be prevented.

  Furthermore, since a plurality of action parts are formed on the elastic plate, and the base sides of these action parts are raised from the support parts respectively, the face part elastically deforms at the impact point of the ball when the ball strikes. The ball is repelled by the action portion corresponding to the striking position among the plurality of action portions. Therefore, since the face portion can be bent at the hitting position of the ball, elasticity of the face portion can be obtained. In addition, even in the case of an off-center hit where the ball is out of the sweet spot, the action portion corresponding to the hitting position of the ball acts to repel the ball, thereby increasing the flight distance even in the off-center hit. it can.

  Furthermore, the support portion of the elastic plate is fixed to the upper and lower inner surfaces of the head body, the action portion is formed between the upper and lower support portions, and the central portion of the action portion is abutted against the inner surface of the face portion. When the face portion is elastically deformed, the action portion moves to the tail side, and the upper and lower support portions are attracted to each other and act in a direction. In the case of the conventional general head, at the time of impact, the crown and sole flex and energy is dispersed, but since the elastic plate suppresses unnecessary deflection at the time of impact, energy is concentrated on the face side, and as a result, The deflection of the face is increased, the initial velocity of the ball can be increased, and the flight distance can be increased.

  Furthermore, when the elastic plate is constituted by an upper set in which the support portion is fixed to the upper inner surface of the head body and a lower upper set fixed to the lower inner surface, the action portion of each set is brought into contact with the inner surface of the face portion. Since the directions of elastic deformation of the action parts of the respective sets are different, it is possible to make the deflection of the face part uniform and to stabilize the hitting direction of the ball.

1 is a front view showing a golf club head according to the present invention. FIG. 1 is a perspective view of a golf club head according to the present invention. FIG. 1 is a plan view of a golf club head according to the present invention. It is a top view which shows a part of elastic board. FIG. 1 is a plan view of a golf club head according to the present invention. FIG. 6 is a cross-sectional view showing a state of the golf club head when hitting a ball. It is a principal part top view showing the state at the time of ball hitting of a golf club head. It is a side view of the modification of an elastic board. It is a front view which shows the 2nd Example of an elastic board. It is a front view which shows the 3rd Example of an elastic board. It is a perspective view which shows the other modification of an elastic board. (A)-(D) are the principal part top views which show another modification. It is sectional drawing which shows the 4th Example of an elastic board. FIG. 21 is a cross-sectional view showing a state of a golf club head in a fourth embodiment of an elastic plate at the time of hitting a ball. FIG. 1 is a front view showing an embodiment of an iron club as a golf club head according to the present invention. It is sectional drawing of the iron club shown in FIG.

  The golf club head according to the present invention comprises a face portion for striking a ball, an elastic plate formed of a metal plate is in contact with the inner surface of the face portion, and the elastic plate is fixed inside the head body. A supporting portion and an operating portion abutting on the inner surface of the face portion, and a reinforcing bead elongated in the longitudinal direction continuously from the operating portion to the supporting portion is formed, and the ball is hit on the face portion The action portion of the elastic plate receives the elastic deformation of the face portion at the same time, and causes the face portion to repel by elasticity.

  Hereinafter, preferred embodiments of the present invention will be described based on the drawings. 1 to 3 show a golf club head according to the present invention. The illustrated golf club head exemplifies a wood type. The head main body 1 is constituted by a crown portion 1a forming an upper surface and a sole portion 1b forming a lower surface, as indicated by a two-dot chain line. Further, a face portion 2 for striking a ball is attached to the head body 1 at an opening on the front surface. Further, at one end of the head main body 1, a tubular neck portion 1c for mounting a shaft (not shown) is formed.

  The action portion 3a of the elastic plate 3 formed of a metal plate is in contact with the inner surface of the face portion 2 of the head main body 1. The elastic plate 3 is formed with a support portion 3b fixed inside the head main body 1 and an action portion 3a abutting on the inner surface of the face portion 2 and continuously reinforcing the action portion 3a from the support portion 3b in the longitudinal direction The bead BD is formed.

  The elastic plate 3 is formed of an elastic metal plate such as titanium alloy, stainless steel, spring steel, phosphor bronze or the like. In the golf club head 1, the weight of the head body 1 itself is approximately 200 g. Therefore, it is desirable to select a metal plate that is relatively lightweight and strong as the elastic plate 3 and that has a predetermined elasticity. As a thing which satisfy | fills such conditions, the (alpha)-(beta) type titanium alloy currently used also for the face part 2, and a (beta) type titanium alloy are suitable. In addition, since the thickness of the metal plate can be made thin by forming a bead for reinforcement on the elastic plate 3, even if using stainless steel, spring steel and phosphor bronze having a large specific gravity, weight reduction is possible like titanium alloy. It is. These metal plates have a thin plate thickness of 0.1 mm to 1.0 mm although they differ depending on the above-mentioned materials. For this reason, the weight of the elastic plate 3 is about 3 g to 6 g, so that it is possible to make the weight of the range of about 200 g required for the golf club head 1.

  As shown in FIGS. 1 to 3, in the elastic plate 3, three action parts 3a are integrally raised from one end side of the support part 3b with a predetermined interval. The rising angle from the support portion 3 b is 80 degrees to 120 degrees. Further, as shown in FIG. 5, the rising portions of the support portion 3b and the three action portions 3a are formed in an arc shape with a predetermined radius. Furthermore, it is desirable that the width of the entire three action parts 3a be equal to or slightly smaller than the width of the sweet spot of the face part 2. And in each action part 3a, a bead BD for reinforcement is formed in the longitudinal direction. The bead BD is continuously formed from the action portion 3a to the support portion 3b. As shown in FIG. 4, the bead BD formed on the elastic plate 3 is formed with ridges 3 c on both sides on the opening side.

  The bead BD is a projection which is formed by pressing a metal plate into a cross-sectional shape which is elongated in the shape of a long, e.g., semicircular cross section, and the concave side is formed like a half pipe. The bead is preferably pressed into the plate and then bent. By performing the bead processing, the bending strength and the bending strength of the metal plate can be increased four times or more with respect to the flat plate, and moreover, the amount of elastic deformation of the acting portion 3a can be changed. Then, in the bead BD formed in the three action parts 3a, a half pie-shaped groove with a width W1 is formed at the center in the width direction of the action parts 3a, and a ridge 3c with a width W2 is formed on both sides thereof. . Further, by changing the depth D and the width W1 of the groove of the bead BD, the amount of elastic deformation of the action portion 3a can be set appropriately. The bead BD is continuously formed from the action portion 3a to the support portion 3b via the rising portion. Since the bead BD is formed in the rising portion, the bending strength in the rising portion is enhanced. Furthermore, the bead BD is also formed on the support portion 3b to increase the strength of the support portion 3b.

  The support portion 3 b of the elastic plate 3 is formed in a plate shape as shown in FIGS. 2 and 3 and is joined to the inner surface of the sole portion 1 b of the head main body 1. The support portion 3b and the inner surface of the sole portion 1b are fixed by rivets 32 as shown, or fixed by screws, welding or adhesion. The fixed strength is set to withstand the pressing force of hitting the ball on the face portion 2.

  The elastic plate 3 fixed to the inner surface of the sole portion 1b is in contact with the sweet spot on the central portion of the face portion 2, as shown in FIG. Of the three action portions 3a, the tip end side of the central action portion 3a is in contact with the center of the sweet spot, and the tip side of the action portions 3a on both sides is in contact with both sides of the sweet spot. Further, it is desirable that the inner surface of the face portion 2 be in contact with the flat surface of the collar portion 3c formed in the action portion 3a, whereby the inner surface of the face portion 2 is prevented from being damaged. In addition, since the tip end side of the acting portion 3a is in contact with the inner surface of the face portion 2 relatively widely, the tip end side of the acting portion 3a is slightly curved along the inner surface shape of the face portion 2 as shown in FIG. I am doing it. Furthermore, the base end of the action portion 3a raised from the support portion 3b is relatively large so as to withstand formation of the bead BD continuously and bending stress when the action portion 3a is elastically deformed. It is desirable to bend in a circular arc. The support portion 3b and the inner surface of the sole portion 1b are sufficiently adhered to each other by a rivet 32 or the like so as to endure the strength sufficiently. However, in order to lower the center of gravity of the head body 1, the inner surface of the sole portion 1b In the case where the weight 4 is installed, it is desirable that the end of the action portion 3a be in contact with the end face of the weight 4 as shown by a two-dot chain line in FIG. Although the three action parts 3a are raised from one end side of one support part 3b, the three action parts 3a are separately provided with a support part, and are raised from one end side of this support part You may

  Next, the action of the elastic plate 3 will be described. Normally, as shown in FIG. 5, the action portion 3 a of the elastic plate 3 is in contact with the inner surface of the face portion 2. Then, as shown in FIG. 6, when hitting the ball 5 on the central portion (sweet spot) of the face portion 2, a pressure of 1 ton or less is applied to the face portion 2, and the central portion of the face portion 2 is bent and bent. . The deflection dimension L varies depending on the swing speed (head speed), but in a general wood type golf club head, it is in the range of approximately 0.1 mm to 1.0 mm. Then, when the central portion of the sweet spot of the face portion 2 is elastically deformed and bent by the impact of the ball 5, at the same time, the acting portion 3 a of the elastic plate 3 is elastically deformed and bent toward the tail side of the head main body 1. At the next moment, the acting portion 3a returns immediately after being pressed, and therefore, repels in the direction of the face portion 2 by a large elastic force. The repulsive force is transmitted to the face portion 2, and the large repulsive force of the action portion 3a is added to the elasticity of the face portion 2 returning to the state shown in FIG. 5, and the ball 5 is struck by the large repulsive force. Thus, when the ball 5 is hit by the central portion of the sweet spot, as shown in FIG. 7, the central portion of the sweet spot of the face portion 2 is elastically deformed and flexed, and the central portion mainly corresponds to the central portion. The action part 3a elastically deforms and repels. On the other hand, the action portions 3 a on both sides elastically deform in accordance with the bending of the face portion 2. Therefore, it is possible to prevent the free elastic deformation of the face portion 2 from being hindered. Further, in the case of an off-center hit where the ball 5 is out of the sweet spot, either the left or right acting part 3a corresponding to the hitting position of the ball 5 acts to repel the ball 5, so the off-center hit. Even if there is, the flight distance can be increased.

  When striking the ball 5, the contact time between the ball 5 and the face portion 2 is shortened by the repulsive force of the elastic plate 3, and even if the elastic modulus of the face portion 2 is low, the contact time is the American Golf Association. It falls within the range of 257 μs defined by the United States Golf Association (USGA). As described above, since the ball 5 is struck by the repulsive force of the elastic plate 3 in addition to the repulsive force of the face portion 2, the ball 5 can greatly extend the flight distance while obtaining a large initial speed by the strong repulsive force.

  FIG. 8 shows a modification of the elastic plate, in which the action portion 13a is bent and formed into a large arc shape from one end side of the support portion 13b of the elastic plate 13. As shown in FIG. Although the action portion 13a shown in FIGS. 1 to 3 is raised from one end side of the support portion 13b by a relatively small arc, when the action portion 13a is elastically deformed several thousand times or more, the stress in the rising portion is May increase and cause metal fatigue. As in the example shown in FIG. 8, by forming the action portion 13a in a large arc shape, the local stress is eliminated, and it is possible to make the elastic plate 13 have a long life.

  FIG. 9 shows a second embodiment of the elastic plate, in which the action portion 23a of the elastic plate 23 is formed of one metal plate, and three beads BD are formed. The supporting portion 23b is erected by forming a predetermined arc from one end side of the supporting portion 23b, as in the embodiment described above. In addition, the structure of the support part 23b is the same as that of the Example mentioned above, and four beads BD are continuously formed to the support part 23b. As described above, even if the action portion 23a is a single metal plate, it is possible to obtain necessary strength by forming a plurality of beads BD, and the face portion 2 can be obtained as in the embodiment described above. The ball 5 can be hit by the repulsive force of the elastic plate 23 in addition to the repulsive force of. The bead BD formed on the action portion 23a is set such that the width, depth or distance is changed, and the amount of elastic deformation is optimized in accordance with the position of the facing face portion 2. Further, as shown in FIG. 9, the upper end of the action portion 23a may be curved to have different heights. As described above, when the action portion 23a is formed of a single metal plate, even if the ball 5 is an off-center hit where the sweet spot is removed, the action portion 23a is elastically deformed due to the twist and the repulsion occurs. Therefore, even an off-center hit can increase the flight distance.

  FIG. 10 shows a third embodiment of the elastic plate in which the elastic plate 33 is divided into the crown portion 1 a and the sole portion 1 b of the head main body 1. The elastic plate 33 of the lower set provided in the sole portion 1b has a configuration obtained by removing the central action portion 3a of the elastic plate 3 shown in FIG. 1, and two action portions 33a These action parts 33a are raised from the support part 33b. The elastic plate 34 of the sole portion 1b is fixed in the same manner as the embodiment described above. On the other hand, in the upper set of elastic plates 34 provided in the crown portion 1a, one action portion 34a is raised from the support portion 34b, and the support portion 34b is fixed to the inner surface of the crown portion 1a. Similar to the above-described embodiment, beads BD are formed on the elastic plates 33 and 34, and ridges 33b and 34b of the action portions 33a and 34a are formed. And the action part 34a of the elastic board 34 of the crown part 1a provides a clearance gap on both sides between the elastic boards 33 provided in the sole part 1b, and is arrange | positioned. The tip end side of the action portion 34 a of the crown portion 1 a is brought into contact with the central portion of the sweet spot of the face portion 2, and the action portion 34 a of the elastic plate 33 of the sole portion 1 b is in contact with the side of the sweet spot of the face portion 2 I am getting in touch. Thus, when the action parts 33a and 34a of each set are brought into contact with the inner surface of the face part 2, the elastic deformation directions of the action parts 33a and 34a of each set are different, so the deflection of the face part 2 is made uniform. And the striking direction of the ball 5 can be stabilized.

  FIG. 11 shows another modification of the elastic plate. In the embodiment described above, the bead BD is raised in a strip shape such as a semicircular shape in cross section by press working, but the bead BD of the elastic plate 3 shown in FIG. . Similar to the elastic plate 3 shown in FIG. 2, the bead BD is continuously formed from the action portion 3a to the support portion 3b via the rising portion. The bead BD is formed to increase the strength of the action portion 3a and to increase the bending strength at the rising portion, but if the strength necessary for the support portion 3b is obtained, as shown in FIG. It may be formed only at the bent rising portion at one end of the portion 3b to give a rib function in sheet metal processing.

  12A to 12D show still another modification of the action portion 3 a of the elastic plate 3. The action part 3a shown to FIG. 12 (A) forms cross-sectional shape in half-pipe shape of semicircle shape, makes it a bead BD, and abbreviate | omits the collar part 3c. In FIG. 12A, the cross-sectional shape is formed into a substantially triangular mountain shape to form a bead BD. The action portions 3 a bring the opening side of the bead BD into contact with the inner surface of the face portion 2. In this example, the inner surface of the face portion 2 is prevented from being damaged by smoothing the corner of the open end surface. FIG. 12C shows an example in which the cross-sectional shape is formed in a semicircular half pipe to make a bead BD, and FIG. 12D is an example in which the cross-sectional shape is formed in a rectangular shape to make a bead BD The heel part 3c is omitted. These prevent the inner surface of the face portion 2 from being damaged by bringing the top side opposite to the bead BD opening side into contact with the inner surface of the face portion 2. As described above, in the present invention, at least the longitudinal direction of the action portion 3a is formed in a half pipe shape, for example, and the one in which the strength is enhanced is also defined as the bead.

  FIG. 13 shows a fourth embodiment of the elastic plate. The elastic plate 40 has the support portion 40a fixed to the upper and lower round portions 1a of the head main body 1 and the inner surface of the sole portion 1b, and the action portion 40b is formed between the upper and lower support portions 40a. The action portion 40b of the elastic plate 40 has its central portion raised corresponding to the sweet spot of the face portion 2, and the top portion of the central portion abuts against the inner surface. Similar to the embodiment of the elastic plate 3 shown in FIGS. 1 to 3, in this elastic plate 40, three acting portions 40b are formed, and the rising portions of the upper and lower support portions 40a and the three acting portions 40b are , Is formed in an arc shape with a predetermined radius. Furthermore, the width of the entire three action portions 40b is the same as or slightly smaller than the width of the sweet spot of the face portion 2, as in the embodiment described above. And in each action part 40b, a bead BD for reinforcement is formed in the longitudinal direction. The bead BD is continuously formed from the action portion 3a to the support portion 3b. Furthermore, ridges are formed on both sides of the open side of each bead BD.

  In the elastic plate 40 configured as described above, as shown in FIG. 13, the top of the action portion 3 a of the elastic plate 40 is in contact with the inner surface of the face portion 2. Then, as shown in FIG. 14, when the ball 5 is hit on the central portion (sweet spot) of the face portion 2, the central portion is bent and bent. Then, when the central portion of the sweet spot of the face portion 2 is elastically deformed and bent by the impact of the ball 5, at the same time, the acting portion 40 b of the elastic plate 40 is elastically deformed and bent toward the tail side of the head main body 1. At the next moment, the acting portion 40b returns immediately after being pressed, so it repels in the direction of the face portion 2 by a large elasticity. This repulsive force is transmitted to the face portion 2 and the large repulsive force of the action portion 40b is applied in addition to the elastic force that causes the face portion 2 to return to the state as shown in FIG. Ru.

  Further, when the ball 5 is hit, the action portion 40b of the elastic plate 40 elastically deforms with the dimension of the deflection amount L and bends toward the tail side of the head main body 1 indicated by the arrow, whereby the upper and lower support portions 40a Act as if they were attracted to each other. In an ordinary wood-type head main body 1, the face portion 2 is bent and the volume in the head main body 1 is reduced at the impact of striking the ball 5, so the upper and lower crown portions 1a and sole portions 1b are outward. And the volume in the head body 1 decreases. Since the energy is dispersed by the bulging, there is a problem that the repulsive force is reduced to reduce the flight distance of the predetermined ball 5. On the other hand, according to the fourth embodiment, since the expansion of the crown portion 1a and the sole portion 1b is prevented by the elastic plate 40, it is possible to obtain the repulsive force inherent to the face portion 2. In addition to the repulsion force inherent to the face portion 2, the repulsion force of the action portion 40 b of the elastic plate 40 makes it possible to increase the flight distance of the ball 5.

  Although not shown, when three action parts 40b are formed, the center action part 40b abuts on the center of the sweet spot of the face part 2, and both action parts 40b abut on both sides of the center of the sweet spot. When the ball 5 is struck by the central portion of the sweet spot, the central portion of the sweet spot of the face portion 2 is elastically deformed and bent, and the central action portion 40b mainly corresponding to the central portion is elastically deformed and repelled. The action portions 40 b on both sides elastically deform in accordance with the deflection of the face portion 2. In the case of an off-center hit in which the ball 5 is out of the sweet spot, one of the left and right action parts 40 b corresponding to the hitting position of the ball 5 acts to repel the ball 5. The ability to increase the flight distance, if any, is the same as in the embodiment described above.

  15 and 16 show an embodiment applied to an iron club as a golf club head according to the present invention. The iron type golf club head (hereinafter abbreviated as "iron head") 50 shown in FIG. 15 is a general structure, and the detailed description thereof will be omitted, but an outline of the structure necessary for the present invention will be described.

  The iron head 50 is composed of a head body 51 and a hosel portion 52 for inserting and fixing a shaft. The head body 51 has a face member 53 fixed to the front side. The face member 53 and the head main body 51 are both made of a metal material. For the face member 53, a metal material having a specific gravity smaller than that of the head main body 51 is used. As a metal material used for the face member 53, for example, titanium, a titanium alloy, an aluminum alloy, a maraging steel, an amorphous alloy or the like is preferable, and a titanium alloy having a low specific gravity and a high strength is particularly preferable. For the head main body 51, for example, stainless steel such as SUS630, SUS255 or SUS450, maraging steel, Ni-based alloy or soft iron is preferable, and stainless steel, soft iron or maraging steel is particularly preferable.

  The face member 51 is formed to have a substantially constant thickness tf except for the face line FL and the like. The face member 53 may have a thin peripheral portion and a thick central portion. The thickness tf of the face member 53 can be appropriately determined depending on the material to be used, and is not particularly limited. However, if it is too small, the durability tends to deteriorate, and if too large, sufficient deflection is obtained when hitting a ball There is a tendency for the flight distance to decrease. Therefore, the thickness tf is preferably 1.0 mm to 4.0 mm.

  The head main body 51 is provided with a face receiving portion 54 on the front side around the opening. The face receiving portion 54 is formed in a substantially step-like cross section including an inner peripheral surface portion 54 a supporting the outer peripheral surface of the face member 53 and a receiving surface 54 b supporting the peripheral portion of the face member 53. Then, the face member 53 is fitted into the face receiving portion 54 of the head main body 51, and is integrally fixed, for example, by bonding means such as bonding, press fitting, caulking, welding or screwing.

  The face member 53 has a circular central thick portion 53a and an annular groove 53b formed so as to surround the outer edge of the central thick portion 53a at the central portion. It is desirable that the central thick portion 53a be centered on the sweet spot point S. Further, in this embodiment, the thickness t5 of the central thick portion 53a is the same as the thickness of the face member 53, but the hitting of the ball is caused by the deflection caused when the ball strikes the central thick portion 53a. It may be increased or decreased by the initial speed.

  The annular groove 53b formed in the outer edge of the central thick portion 53a is formed with a slope 53c inclined from the periphery of the central thick portion 53a toward the bottom of the annular groove 53b, and the outer edge side of the annular groove 53b is a face A wall surface 53e substantially perpendicular to the face surface of the member 53 is formed, whereby the cross-sectional shape is formed in a substantially V-shape. The thickness t6 between the bottom of the annular groove 53b and the face surface is 0.1 mm to 0.9 mm.

  Furthermore, the slope 53c also reduces the thickness smoothly from the peripheral edge of the central thick portion 53a toward the bottom of the annular groove 53b. This prevents the occurrence of a large rigidity step between the central thick portion 53a and the annular groove 53b, and effectively prevents the deterioration of durability due to stress concentration at the time of hitting a ball. In addition, you may form the inclined surface 53c in concave shape in cross-sectional shape. Further, by forming the outer edge side of the annular groove 53b on the wall surface 53e substantially perpendicular to the face portion 53, the rigidity of the thick face portion 53 causes the annular groove 53b to be mainly bent, and as a result, It further contributes to increasing the flight distance by further improving the resilience performance.

  The iron head 50 configured as described above is provided with an elastic plate 60 substantially the same as the above-described embodiment. The elastic plate 60 is a support portion 60b fixed by appropriate fixing means such as caulking, welding, or screws in a cavity which is the inner surface of the sole of the head main body 51, and an action portion 60a bent from one end of the support portion 60b. Is formed. The action portion 60a is one because the iron head 50 is relatively small. The distal end side of the action portion 60 a is in contact with the center of a circular thick central portion 53 a formed at the central portion of the face member 53. Further, the elastic plate 60 provided on the iron head 50 is also continuous with the support portion 60b from the action portion 60a, and a reinforcing bead BD is formed in the longitudinal direction.

  When the ball of the face member 53 of the iron head 50 is hit, the circular thick central portion 53a formed at the central portion is pressed and elastically deformed by about 0.1 mm to 0.5 mm and the acting portion 60a of the elastic plate 60. The distal end side is pressed to be elastically deformed. Immediately after that, the repulsive force of the action portion 60a of the elastic plate 60 is applied to the repulsive force of the face member 53, and the ball is hit with a large repulsive force. As described above, since the annular groove 53b is formed on the outer edge of the central thick portion 53a in the face member 53, when the ball is struck on the central thick portion 53a, the peripheral annular groove 53b is formed. Since the amount of deflection is increased by this, it is possible to obtain a large repulsive force to hold the ball. However, since the bottom of the annular groove 53b is thin, it may not return to its original position after hitting the ball. However, when the tip end side of the acting portion 60a of the elastic plate 60 abuts on the inner surface of the central thick portion 53a formed in the central portion, it is pressed in the return direction of the central thick portion 53a by the repulsive force of the acting portion 60a. It is possible to always reset to the home position.

  As mentioned above, although this invention was concretely demonstrated based on the Example, this invention is not limited to the said Example, In the range which does not deviate from the summary, it can deform variously. For example, in the above-described embodiment, the longitudinal direction of the action portion of the elastic plate is the vertical direction of the golf club, but may be provided in the horizontal direction or in the inclined direction. Further, in the case where the action portion of the elastic plate is plural, the width and depth of the bead may be individually changed, and further, the plate thickness may be changed.

Reference Signs List 1 head body 1a crown portion 1b sole portion 2 face portion 3 elastic plate 3a action portion 3b support portion 3c rim portion 5 ball BD bead

Claims (5)

A golf club head comprising a face portion for striking a ball, wherein
An elastic plate formed of a metal plate is in contact with the inner surface of the face portion,
The elastic plate is formed with a support portion fixed to the inside of the head main body, and an action portion abutting on the inner surface of the face portion, and a bead for reinforcement is provided continuously from the action portion to the support portion. Formed
A golf club head characterized in that the action portion of the elastic plate receives the elastic deformation of the face portion when the ball is hit on the face portion and causes the face portion to repel the elasticity by elasticity.   The said action part of the said elastic board formed the collar part in the both sides of the opening side of the bead formed in the longitudinal direction, The said collar part of the said bead was made to contact the inner surface of the said face part. Golf club head.   3. The golf club head according to claim 1, wherein the elastic plate forms a plurality of the acting portions, and the base sides of the acting portions are respectively raised from the support portion.   The elastic plate fixes the support portion to the upper and lower inner surfaces of the head body, forms the action portion between the upper and lower support portions, and causes the central portion of the action portion to abut on the inner surface of the face portion. A golf club head according to any one of claims 1 and 2.   The elastic plate comprises an upper set in which the support portion is fixed to the upper inner surface of the head main body, and a lower set fixed to the inner surface of the head main body. The golf club head according to claim 1, wherein the golf club head is in contact.

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