JP5074779B2 - Manufacturing method of golf club head - Google Patents

Description

  The present invention relates to a method for manufacturing a golf club head capable of manufacturing a golf club head having high durability.

  In recent years, it has been proposed to manufacture a golf club head by adhering two or more members made of different metal materials. For example, Patent Document 1 below describes that a golf club head is manufactured by fixing a steel head body and a weight member made of a tungsten alloy by welding.

JP 2004-135991 A

  However, two separately manufactured members may each have unavoidable manufacturing errors. For this reason, when two members are fitted together prior to welding, the positions of both members may be displaced or the joint surfaces may not be in close contact with each other, and the positions of both members may not be stable. If welding is performed in such a state, a gap remains between both members, and damage starting from this gap is likely to occur during use. That is, the durability of the club head may be deteriorated.

  The present invention has been devised in view of the above circumstances, and prior to welding, by applying pressure to a temporary assembly in which two members are fitted together by a press, the joint surfaces of these members are brought into close contact with each other. The main object is to provide a golf club head manufacturing method capable of manufacturing a highly durable golf club head by reducing the gap between two members on the basis of performing the bonding surface correction process.

The invention according to claim 1 of the present invention is a method of manufacturing a golf club head by fixing at least two members, the step of manufacturing a first member made of a metal material and having a recess, A step of manufacturing a second member made of a metal material different from that of the first member and capable of being fitted into the recess, and a temporary assembly in which the second member is fitted into the recess of the first member And by applying pressure to the temporary assembly by pressing, at least a part of the inner peripheral surface of the recess and / or the outer peripheral surface of the second member facing the inner peripheral surface is plastically deformed. Welding step for welding the inner peripheral surface and the outer peripheral surface, and welding for welding a boundary portion between the first member and the second member appearing on the outer surface of the temporary assembly that has undergone the bonding surface correction step. a step seen including, the first member, A head body having a hosel portion into which a shaft is inserted, and a face base portion provided with a face attachment portion connected to the hosel portion via a neck portion and attached to a separate face member on the front surface, and the second body The member is a weight member having a specific gravity greater than that of the head body, and the face base portion has an opening, the face mounting portion is provided around the opening, and a sole portion extending below the opening. The concave portion is provided in the frame, and the concave portion has a bow shape extending from the toe to the heel along the opening, and the concave portion is connected to the bottom surface recessed from the outer surface of the head and the upper edge side of the bottom surface and is a club. At least an upper wall surface extending rearward of the head in a direction intersecting with the face, and the recess is formed from the bottom surface and the upper wall surface. The center portion that is open at the rear and the lower side, and the toe side of the center portion, and the bottom surface, the upper wall surface, the lower edge side of the bottom surface, and the club face are extended to the back of the head. By having a toe-side lower side wall surface, only the rear side is opened, and the center part is connected to the heel side, and the bottom surface, the upper wall surface, and the bottom edge side of the bottom surface are connected and intersects the club face. It has a heel side portion that is open only on the rear side by having a lower side wall surface on the heel side that extends rearward in the head .

  According to a second aspect of the present invention, the bonding surface correction step is performed by holding the temporary assembly in a female mold having a cavity and pressing the temporary assembly toward the cavity by a male mold. A golf club head manufacturing method according to Item 1.

According to a third aspect of the present invention, the first member includes a hosel portion into which a shaft is inserted, and a face attachment portion that is connected to the hosel portion via a neck portion, and a separate face member is attached to the front surface. The second member is a weight member made of a tungsten alloy having a specific gravity larger than that of the head body, and the face member is attached to the first member after the welding step. The golf club head manufacturing method according to claim 1, further comprising a face attaching step of non-welding the face attaching portion of the member.

According to a fourth aspect of the present invention, the weight member is inserted into the concave portion from the rear side of the head main body, and the bonding surface correction step includes the temporary assembly, the back face side of the lower side and the lower side thereof. The face virtual surface, which will later become the club face, is held substantially horizontal by being placed in the female cavity so that the face side faces upward, while the peripheral edge of the back surface of the face member of the face mounting portion By pressing the male mold against the entire circumference of the annular receiving surface that supports the part and applying a vertical downward force to the temporary assembly, the temporary assembly is compressed between the male mold and the female mold and receives pressure. The golf club head manufacturing method according to claim 1, wherein the golf club head manufacturing method is performed.

  In the golf club head manufacturing method of the present invention, a first member made of a metal material and having a recess, and a second member made of a metal material different from the first member and capable of being fitted into the recess. Each is manufactured. Then, by forming a temporary assembly in which the second member is fitted in the recess of the first member, and applying pressure to the temporary assembly by pressing, the inner peripheral surface of the recess and / or the inner peripheral surface A joining surface correction process is performed in which at least a part of the outer peripheral surface of the second member facing each other is plastically deformed to bring the inner peripheral surface and the outer peripheral surface into close contact with each other. Therefore, the first member and the second member are closely fitted and can be effectively suppressed from generating a large gap therebetween. And after a joint surface correction process, a highly durable golf club head is manufactured by welding the boundary part of the 1st member and the 2nd member which appear on the outer surface of a temporary assembly.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a front view of a reference state of a golf club head 1 manufactured by the method of manufacturing a golf club head according to the present invention, FIG. 2 is a rear view thereof, FIG. 3 is an end view taken along line AA in FIG. 2 and 5 are an exploded view of the club head before assembly. The reference state of the golf club head 1 is a state in which the club is held at the lie angle α and the loft angle β and is grounded to the horizontal plane HP. Is described as being placed in

  In the present invention, the golf club head is manufactured by fixing at least the first member P1 and the second member P2. In this embodiment, the case where the golf club head 1 is an iron type manufactured by fixing three members including the third member P3 will be described as an example.

  In the figure, a golf club head (hereinafter, also simply referred to as “head”) 1 includes a face member 2 constituting a main part of a club face F that hits a ball, and a head having the face member 2 disposed on the front surface. The main body 3 and the weight member 4 made of a material provided on the sole side of the head main body 3 and having a specific gravity larger than that of the head main body 3 are configured. Here, the head body 3 corresponds to the first member P1, the weight member 4 corresponds to the second member P2, and the face member 2 corresponds to the third member P3.

  In the present embodiment, the face member 2 and the head body 3 are made of different metal materials. As a preferred embodiment, a metal material having a specific gravity smaller than that of the head body 3 is used for the face member 2. For example, an aluminum alloy, titanium, a titanium alloy, or a magnesium alloy is preferably used for the face member 2, while a steel material such as stainless steel or maraging steel is preferably used for the head body 3. As a result, more weight is distributed around the face member 2, and as a result, the head 1 is provided that is excellent in the direction of a hit ball having a large moment of inertia and a sweet area.

  The face member 2 is formed of a plate-like body. In this embodiment, the face member 2 has a substantially constant thickness t excluding narrow grooves such as the face line FL. However, the thickness of the face member 2 may be decreased stepwise or continuously toward the central portion, or may be increased conversely. The contour shape of the face member 2 preferably increases gradually from the heel side to the toe side, for example, in accordance with the contour of the head body 3. Thereby, a wider range of the club face F can be constituted by the face member 2.

  The thickness t of the face member 2 is not particularly limited, but if it is too small, the durability tends to deteriorate, whereas if it is too large, the resilience performance of the head 1 tends to decrease. For this reason, the thickness t is preferably 1.5 mm or more, more preferably 1.8 mm or more, and further preferably 2.0 mm or more. The upper limit is preferably 4.0 mm or less, more preferably Is preferably 3.5 mm or less, more preferably 3.0 mm or less.

  The head body 3 has a face provided with a hosel portion 5 into which a shaft (not shown) is inserted, and a face attachment portion 8 connected to the hosel portion 5 via a neck portion 6 and attached to the front face member 2. And a base 7. The lie angle α of the head 1 can be set with reference to the axial center line of the shaft insertion hole 5a of the hosel portion 5.

  As shown in FIG. 5, the face base 7 includes a top frame 7a extending at the top of the head and extending in the heel direction, a top frame 7a extending at the bottom of the head and a sole frame 7b extending in the heel direction, and a toe side of the head. A toe portion frame 7c that connects between the top portion frame 7a, a toe portion frame 7c, a sole portion frame 7b, and a neck portion 6 and a single opening O that penetrates in the front-rear direction of the head.

  Around the opening O, a face attachment portion 8 for attaching the face member 2 is provided. The face mounting portion 8 has an annular receiving surface 8A that supports the peripheral edge of the back surface of the face member 2, and an inner peripheral surface that extends from the outer peripheral edge of the receiving surface 8A toward the face center and can hold the outer peripheral surface of the face member 2. And 8B.

  The sole frame 7 b of the face base 7 is provided with a recess 9 for attaching the weight member 4. The concave portion 9 of the present embodiment is formed in a substantially bow shape extending from the toe to the heel along the opening O.

  The concave portion 9 is recessed from the outer surface of the head, and in the present embodiment, the bottom surface 10 extends substantially parallel to the club face F, and is connected to the upper edge 10a of the bottom surface 10 so as to cross the club face F from the upper edge 10a. An inner peripheral surface including an upper wall surface 11 extending rearward and reaching the outer surface of the head, and a lower wall surface 12 continuing to the lower edge 10b of the bottom surface 10 and extending rearward from the lower edge 10b and intersecting the club face F. It is divided by.

  Further, the concave portion 9 of the present embodiment includes, based on the cross-sectional shape thereof, a central portion 9c extending substantially in the middle region in the toe-heel direction, a toe side portion 9t continuous to the toe side of the central portion 9c, and the central portion It can be divided into a heel side portion 9h connected to the heel side of 9c.

  The central portion 9c of the concave portion 9 extends from the sole portion frame 7b, and its inner peripheral surface is composed of the bottom surface 10 and the upper wall surface 11, and the lower wall surface 12 is not provided. As a result, as shown in FIG. 3, the central portion 9c of the recess 9 is open at the rear and lower sides of the head.

  On the other hand, the toe side portion 9t of the recess 9 extends to the toe portion frame 7c, and its inner peripheral surface is constituted by the bottom surface 10, the upper wall surface 11, and the toe side lower wall surface 12t. As a result, only the rear side of the toe side portion 9t is opened. Further, the toe side portion 9t is formed in a tapered shape so as to become smaller toward the end.

  Similarly, the heel side portion 9h of the recess 9 extends to the neck portion 6, and the inner peripheral surface thereof includes the bottom surface 10, the upper wall surface 11, and the heel side lower side wall surface 12h. Thereby, the heel side part 9h of the recessed part 9 is opened only at the rear of the head. Further, the heel side portion 9h is also formed in a tapered shape so as to become smaller toward the end.

  The weight member 4 is made of a metal material having a specific gravity greater than that of the head body 3. By fixing the weight member 4 made of such a high specific gravity material to the head body 3, the center of gravity of the head 1 can be adjusted to an optimum position. In the present embodiment, the weight member 4 is fixed to the concave portion 9 provided at the rear and below the above-described head, so that the center of gravity of the head 1 can be set at the rear and at a lower position.

  The weight member 4 needs to be a metal material having a specific gravity greater than that of the head body 3 and capable of being welded to the head body 3. Such a metal material is not particularly limited because it is determined by the combination with the head body 3. As an example, when the head body 3 is made of a steel material such as stainless steel or soft iron, the weight member 4 is preferably a W—Fe—Ni alloy containing iron and / or nickel in tungsten.

  The tungsten alloy preferably contains 15 to 50% by weight of W, 12 to 30% of Fe, and 30 to 69% of Ni. If W is less than 15 wt%, the specific gravity cannot be increased. Conversely, if it exceeds 50 wt%, the hot water flow becomes worse, and it may be difficult to form with high precision by casting. If Fe is less than 12 wt%, welding to the steel head main body 3 may not be possible. Conversely, if it exceeds 30 wt%, rust prevention may be reduced. Furthermore, if Ni is less than 30 wt%, the corrosion resistance may be reduced. Conversely, if Ni is more than 60 wt%, the strength may be reduced and the specific gravity may be reduced.

  The specific gravity of the weight member 4 is preferably 8.5 or more, more preferably 9.0 or more in order to effectively adjust the center of gravity of the head 1. On the other hand, if the specific gravity of the weight member 4 is too large, the material cost may increase, so it is preferably 13.0 or less, more preferably 12.5 or less. The weight member 4 can be manufactured by various methods such as casting, forging, cutting or sintering, and casting capable of precision molding is particularly desirable.

  The weight of the weight member 4 is not particularly limited, but if it is too small, the effect of adjusting the center of gravity may not be sufficiently obtained. Conversely, if the weight member 4 is too heavy, the head main body 3 Therefore, there is a possibility that the usable weight is limited and the club head 1 may be downsized. From such a viewpoint, the weight of the weight member 4 is preferably 40 g or more, more preferably 50 g or more, and further preferably 55 g or more, and the upper limit is preferably 100 g or less, more preferably 90 g or less, still more preferably Is preferably 80 g or less.

  The weight member 4 of the present embodiment corresponds to the shape of the concave portion 9, and is formed in a substantially bow shape that extends in the toe and heel directions and has both end portions smoothly curved upward. More specifically, the weight member 4 includes a back surface 4a facing the bottom surface 10 of the recess 9, an upper surface 4b facing the upper wall surface 11 of the recess 9, and the lower side wall surfaces 12t and 12h on the toe side and heel side of the recess 9. And a lower surface 4c that can be exposed to the outer surface of the head. The weight member 4 is formed to be slightly smaller than the inner surface dimension of the concave portion 9 so that the weight member 4 can be inserted into the concave portion 9 by a slight force of fingers.

  A method for manufacturing the head 1 as described above will be described. First, the face member 2 (third member P3), the head body 3 (first member P1), and the weight member 4 (second member P2) are separately manufactured. These are produced using one or more methods such as plastic deformation by casting, forging or pressing. In the present embodiment, the face member 2 is manufactured by press molding, and the head body 3 having the recess 9 and the weight member 4 fitted into the recess 9 are both manufactured by casting.

  Next, the process of forming the temporary assembly of a club head by fitting the weight member 4 in the said recessed part 9 of the head main body 3 is performed. As shown in FIG. 3, since the lower wall surface 12 is not provided in the central portion 9c of the recess 9, the weight member 4 can be easily inserted into the recess 9 from the back of the head. Therefore, it is preferable in that the weight member 4 can be easily inserted.

  6 (a) and 6 (b) show schematic cross-sectional views taken along the lines XX and YY of FIG. 2, respectively. As is clear from the figure, the toe side portion 9t and the heel side portion 9h of the recess 9 have a bottom surface 10, an upper wall surface 11 and a lower wall surface 12, so that the weight member 4 temporarily inserted into the recess 9 is The upper and lower sides are held. Therefore, the joining state of the head main body 3 and the weight member 4 is stabilized, and as a result, the positional deviation and easy separation can be prevented. For example, it is preferable that the weight member 4 can be prevented from falling off the head body 3 without being supported by a jig or the like, and as a result, productivity can be improved. Furthermore, such fitting is useful for exhibiting high joint strength even after, for example, main joining by welding.

  However, the shape of the weight member 4 (and the concave portion 9) is not limited to the above-described embodiment, and can be implemented by being modified into various shapes. For example, as shown in FIG. 7 (a), only the sole frame 7b may be extended, or as shown in FIG. 7 (b), the periphery of the face base may be extended annularly. Furthermore, as shown in FIG. 7C, the weight member 4 may be provided in two or more parts. The weight member 4 of this embodiment is shown to include a toe side weight member 4t and a heel side weight member 4h.

  Next, in the manufacturing method of the present invention, as shown in FIG. 8, by applying pressure to the temporary assembly 15 by pressing, the inner peripheral surface of the recess 9 and / or the weight member 4 facing the inner peripheral surface is formed. A joint surface correction process is performed in which at least a part of the outer peripheral surface is plastically deformed to bring these joint surfaces into close contact with each other.

  In the bonding surface correction process of this embodiment, the temporary assembly 15 is placed on a metal female mold M1 having a cavity 20. For example, the temporary assembly 15 is placed in the cavity 20 so that the back face side faces the lower side and the face side faces the upper side. Further, the club face F or the face virtual surface VF that will later become the club face F is held substantially horizontally. Further, the cavity 20 has an inner surface 20a substantially equal to the outer surface on the back face side of the finished head. Thereby, the female mold M1 can support the temporary assembly 15 that receives the vertical force substantially immovably.

  Next, for example, a male mold M2 is pressed against the entire circumference of the receiving surface 8A of the face mounting portion. For example, a fluid pressure actuator (not shown) is linked to the male mold M2, and a vertical downward force is applied to the temporary assembly 15. Accordingly, the temporary assembly 15 is compressed between the male mold M2 and the female mold M1 and receives pressure, whereby the concave portion 9 of the head body 3 and the weight member 4 can be strongly adhered to each other. At this time, at least a part of the head body 3 and the weight member 4 having lower strength or both of them are plastically deformed. This reduces gaps and backlashes at the joint surface, and allows both members to fit more closely together. The “press” includes various types such as a hydraulic type, a pneumatic type, a hydraulic type, and a mechanical type as long as the pressure can be applied to the temporary assembly 15.

  Next, the temporary assembly 15 that has undergone the joint surface correction step is removed from the mold, and as shown in FIG. 9, a welding step of welding the boundary portion E between the head body 3 and the weight member 4 that appears on the outer surface is performed. Done. Various methods can be used for the welding process. For example, TIG welding, plasma welding, laser welding, brazing, or the like is desirable. In particular, laser welding is desirable in which the width of the metal melted portion B is small and the thermal influence on the surroundings is small.

  After the welding process, a face attachment process for joining the face member 2 to the face attachment portion 8 of the head body 3 is performed. As shown in FIG. 10, the face attaching step is the same as the female mold M1 used in the joint surface correcting step. That is, the temporary assembly 15 welded to the cavity 20 of the female mold M1 is placed, and the face member 2 is placed on the face mounting portion 8.

  A squeezing convex portion 17 is provided around the face mounting portion 8 in advance, while a groove-shaped cutout portion 19 is provided for the crushed convex portion 17 to enter the front edge of the face member 2. Is provided in advance. Accordingly, the face member 2 can be attached to the head main body 3 by so-called caulking by pressing the convex portion 17 with the punch M3 and pushing the plastically deformed portion into the notch portion 19.

  It is also possible to weld the weight member 4 to the head body 3 after the face member 2 and the head body 3 are fixed first. However, in this case, the metal structure of the face member 2 is transformed due to the thermal effect during welding, and durability and resilience may be impaired. In this embodiment, such a problem can be prevented. Further, by fixing the face member 2 to the head main body 3 by non-welding joining such as caulking, it is possible to prevent the joint strength of the welded portion between the weight member 4 and the concave portion 9 that have been secured first from being lowered by heat during welding. it can. In addition, as non-welding joining, in addition to the above-mentioned crimping, press-fitting or the like is preferable, and it goes without saying that an adhesive can be used in any case. Thereafter, the club head 1 of the present invention is manufactured through necessary processes such as polishing and painting.

  As mentioned above, although embodiment of this invention was described, this invention can be implemented in a various aspect. For example, in the above-described embodiment, the member constituted by three members (face member 2, head body 3 and weight member 4) is shown, but it may be constituted by four or more members. Conversely, the face member and the head body can be integrally formed of the same material.

  Three iron-type golf club heads were manufactured based on the manufacturing method shown in Table 1. The outline of each example is as follows.

<Comparative Example 1>
Separately, a face member, a head body, and a weight member were prepared with the following specifications. Then, after joining the head main body and the weight member by laser welding, the face member was fixed to the head main body by caulking. The joint surface correction process is not performed.

<Comparative example 2>
Before fitting to the head body, the weight member alone was compressed by a press using a mold to improve the dimensional accuracy of the shape (correction press). Others are the same as those of Comparative Example 1.

<Comparative Example 3>
Before fitting, the head body and the weight member were each compressed by a press using a die to improve the dimensional accuracy of the shape (correcting press). Others are the same as those of Comparative Example 1.

<Example 1>
The head main body and the weight member were fitted together to obtain a temporary assembly, which was compressed by a press to perform a joint surface correction step. Thereafter, after the head main body and the weight member were joined by laser welding, the face member was fixed to the head main body by caulking.

<Example 2>
First, the face member was fixed to the head body by caulking. Next, a weight member was fitted to the head body to obtain a temporary assembly, which was compressed by a press to perform a bonding surface correction step. Thereafter, the head body and the weight member were joined by laser welding. That is, in Example 2, the face attachment process was performed prior to the bonding surface correction process.
Processes other than those described in Table 1 and common specifications of the head are as follows.

Number: 3 iron with a loft angle of 20 degrees and a lie angle of 59.5 degrees
Head body material: SUS630 cast product Head body specific gravity: 7.8
Head body weight: 140g
Face member material: Ti-6Al-4V press-molded product Specific gravity of face member: 4.5
Weight of face member: 35g
Material of the weight member: cast tungsten alloy The composition of the tungsten alloy is as follows.
W: 20 wt%, Fe: 15 wt%, Ni: 60 wt%, Cr: 3 wt% and the balance (C, Si, Mn, N, etc.)
Specific gravity of the weight member: 9.5
Weight of weight member: 60g

  Next, SRI Sports' carbon shaft (MP400, Flex R) was fixed to each club head to produce an iron-type golf club, and the durability of these was tested. The durability test is performed by attaching each test club to a swing robot and hitting a commercially available golf ball (“XXIO DC (XXIO is a registered trademark of the company)) made by SRI Sports at a head speed of 40 m / s. Then, every 100 balls, the presence or absence of damage to the club head was confirmed with the naked eye, and the test was completed when damage occurred.

  The test results are shown in Table 1. It was confirmed that the club heads of Examples 1 and 2 had excellent durability. In particular, in Example 1 in which the face attachment process was performed after the joint surface correction process, the face attachment process was performed prior to the joint surface correction process as a result of preventing deformation of the face member due to heat during welding. Compared to Example 2, it was confirmed to have higher strength.

It is a front view of a head in a reference state showing an embodiment of the present invention. FIG. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG. FIG. (A) And (b) is XX and YY sectional drawing of FIG. (A)-(c) is a rear view of the head which shows other embodiment of a weight member. It is sectional drawing which shows an example of a joint surface correction process. It is a rear view of the temporary assembly after a welding process. It is sectional drawing which shows a face member attachment process.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Golf club head 2 Face member 3 Head main body 4 Weight member 7 Face base 9 Recess 9c Recess center 9t Recess toe side 9h Recess heel side P1 1st member P2 2nd member P3 3rd member F Club Face

Claims (4)

A method of manufacturing a golf club head by adhering at least two members,
Manufacturing a first member made of a metal material and having a recess;
Producing a second member made of a metal material different from the first member and capable of being fitted into the recess;
Forming a temporary assembly in which the second member is fitted into the recess of the first member;
By applying pressure to the temporary assembly by pressing, a part of the inner peripheral surface of the recess and / or the outer peripheral surface of the second member facing the inner peripheral surface is plastically deformed, and the inner peripheral surface A bonding surface correction step for closely contacting the outer peripheral surface;
Look including a welding step of welding the boundary between the first member and the second member appearing on the outer surface of the temporarily assembled body through said bonding surface correction step,
The first member includes a hosel portion into which a shaft is inserted, and a face base portion provided with a face attachment portion that is connected to the hosel portion via a neck portion and to which a separate face member is attached on the front surface. Consists of and
The second member is a weight member having a specific gravity greater than that of the head body,
The face base has an opening and the face mounting portion is provided around the opening, and the recess is provided in a sole frame extending below the opening, and
The concave portion has a bow shape extending from the toe to the heel along the opening,
The concave portion has at least a bottom surface recessed from the outer surface of the head and an upper wall surface that extends to the upper edge side of the bottom surface and extends to the rear of the head in a direction intersecting the club face.
And the said recessed part consists of the said bottom face and the said upper wall surface, and the center part by which back and the downward direction were open | released,
Only the rear side is opened by having a toe side lower side wall surface that extends to the rear side of the head in a direction crossing the club face and continuing to the bottom edge side of the bottom surface, the upper wall surface, and the bottom surface. The toe side,
By having a lower side wall surface on the heel side that extends to the rear side of the head in a direction crossing the club face and continuing to the bottom edge side of the bottom surface, the upper wall surface, and the bottom surface, the rear side is opened. And a heel side portion . A method of manufacturing a golf club head, comprising:   The golf club head manufacturing method according to claim 1, wherein the bonding surface correction step is performed by holding the temporary assembly in a female mold having a cavity and pressing the temporary assembly toward the cavity by a male mold. Method. The first member includes a hosel portion into which a shaft is inserted, and a face base portion provided with a face attachment portion that is connected to the hosel portion via a neck portion and to which a separate face member is attached on the front surface. And the second member is a weight member made of a tungsten alloy having a specific gravity larger than that of the head body,
The golf club head manufacturing method according to claim 1, further comprising a face attaching step of non-welding the face member to the face attaching portion of the first member after the welding step. The weight member is inserted into the recess from the back of the head body,
In the bonding surface correction step, the temporary assembly is placed in a female cavity so that the back face side faces the lower side and the face side faces the upper side. While being held substantially horizontal,
The male assembly is pressed against the entire circumference of the annular receiving surface that supports the peripheral edge of the back surface of the face member of the face mounting portion, and a vertical downward force is applied to the temporary assembly, so that the temporary assembly becomes a male type and a female type. 4. The method of manufacturing a golf club head according to claim 1, wherein the golf club head is compressed by being compressed and subjected to pressure .

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