JP2006000620A - Golf club shaft - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To securely fix a grip to a shaft body, to achieve differentiation of appearance, to improve flexural strength, flat strength, vibration damping characteristics or the like of a grip part, and to obtain a lightweight golf club shaft. <P>SOLUTION: Reticulated mesh sheet material 6 (a mesh member) is interposed between the shaft body 5 and the grip 3. Alternatively, the mesh sheet material 6 (an exposed part 6A) is exposed from the grip 3 for visually recognizing from outside so as to achieve differentiation of the appearance. On a side of a grip fitting end part 7 of the shaft body 5 formed of steel, the mesh sheet material 6 formed of CFRP, carbon fiber reinforced plastic having meshes or other uneven shapes is circumferentially fixed to an outer circumferential side, so that the grip 3 is fixed to the outer circumferential side of the mesh sheet material 6. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a golf club shaft, and more particularly to a golf club shaft that can be reduced in weight and improved in strength, and further can have a grip fixed to a shaft body and differentiated in appearance.

  In the conventional golf club shaft, when the grip is attached to the grip attachment end portion of the shaft main body, the grip is fixed to the shaft main body using an adhesive or the like.

  It is desirable to improve the bending strength, flatness strength, vibration damping property, and the like of the shaft main body portion to which the grip is fixed. In particular, it is required to reduce the weight of the golf club shaft together with these strengths.

  In the follow-through at the end of the swing, the grip portion of the shaft body, particularly the grip portion, may bend and hit the golfer's shoulder, and reinforcement measures are required to prevent this.

  Further, the outer peripheral surface of the shaft body is generally smooth, and there are various problems such as that the grip is not completely fixed to the shaft body, and the certainty of the fixed state may vary depending on the operator. . Therefore, in order to avoid such various problems, there is a problem that the number of processing steps is increased in order to surely perform the fixing operation, and the productivity is affected.

Furthermore, there are various types of golf clubs such as wood, iron, and putter, and it is required that each type or each golfer be easily identified from the appearance as a golf club shaft. Although measures such as winding a colored tape around an arbitrary part of the shaft main body are adopted, there is a problem that the tape is peeled off during use.
Japanese Patent Laid-Open No. 10-15132

  The present invention has been made in view of the above-described problems, and provides a golf club shaft capable of improving various strength characteristics such as bending strength, flatness strength and vibration damping property of a grip portion. Let it be an issue.

  Another object of the present invention is to provide a golf club shaft capable of reducing the weight and improving the strength of the grip portion.

  Another object of the present invention is to provide a golf club shaft that can securely fix the grip to the shaft body.

  Another object of the present invention is to provide a golf club shaft that can be differentiated in appearance.

  That is, according to the present invention, a mesh member having a mesh shape or a stitch is interposed between the shaft main body and the grip, or the mesh member is exposed from the grip so that the mesh member can be visually recognized from the outside so as to be differentiated in appearance. A golf club shaft having a steel shaft main body to which a grip is attached at one end and a club head is attached at the other end, the grip attaching end side of the shaft main body. A golf club shaft characterized in that a mesh member made of a carbon fiber reinforced plastic material is fixed in a circumferential direction on the outer peripheral side of the mesh member, and the grip can be fixed on the outer peripheral side of the mesh member.

  The mesh member may be a mesh sheet material formed by knitting a fiber material into a sheet shape.

  The mesh member may be a mesh-like carbon fiber reinforced plastic material formed by winding a fiber material made of carbon fiber reinforced plastic directly around the shaft body by a filament winding method.

  The mesh member may be a mesh-like carbon fiber reinforced plastic material formed by winding a fiber material made of carbon fiber reinforced plastic directly around the shaft body by a braiding method.

  The mesh member is formed by knitting a fiber material, and the row of the fiber material extending linearly in at least one direction in the mesh member can be oriented in the circumferential direction of the shaft body.

  The mesh member is formed by knitting a fiber material, and the row of the fiber material extending linearly in at least one direction in the mesh member can be oriented in the axial direction of the shaft body.

  The mesh member is formed by knitting a fiber material, and the row of the fiber material linearly extending in at least one direction in the mesh member is oriented at an arbitrary angle with respect to the axial direction of the shaft body. Can do.

  The mesh member may be formed by knitting a fiber material, and may have a row of the fiber material extending linearly in three different directions from each other in the mesh member.

  The mesh member may be formed by knitting a fiber material, and may have a row of the fiber material extending linearly in four different directions in the mesh member.

  The mesh member is formed by knitting a fiber material, and the fiber material is oriented in the axial direction of the shaft body, the fiber material is oriented in the circumferential direction of the shaft body, and The axial direction and the circumferential direction of the shaft body can have two rows of the above-mentioned fiber material oriented at an inclination angle of 45 degrees and orthogonal to each other.

  The mesh member can be formed by knitting a fiber material by sixth stitch.

  The mesh member can be configured to form a hexagonal stitch by knitting a fiber material.

  The mesh member can be configured to form a pentagonal stitch by knitting a fiber material.

  The mesh member can be formed by knitting a fiber material made of prepreg.

  The mesh member is constituted by a member having a mesh-like belt-like fiber portion and a mesh portion between the belt-like fiber portions, and is exposed to the club head side from the grip, and the shaft is passed through the mesh portion. The ground color of the main body can be made visible.

  The mesh member is composed of a member having a mesh-like belt-like fiber part and a mesh part between the belt-like fiber parts, and is exposed to the club head side from the grip. This can be colored into a color that is visible through this mesh portion of the mesh member.

  The mesh member may have 1 to 30 mesh portions or intersections per square centimeter as the mesh roughness.

  The mesh member can have a circumscribed circle diameter of the mesh portion of 0.5 to 10 mm.

  The mesh member is formed by knitting a fiber material, and the width of the fiber material can be 0.2 to 5 mm.

  The mesh member is formed by knitting a fiber material, and the thickness of the fiber material can be 0.05 to 0.50 mm.

The mesh member can have a weight of 80 to 240 g / m ² .

  The mesh member is preferably formed in a mesh shape having a predetermined shape. Here, the “mesh shape” is a “penetrating portion” (mesh-like transmission portion) and a “plane” as a gap in a flat sheet material. By knitting so as to form a stitch as a gap with an arbitrary fiber material, a shape that forms an “intersection” (planar mesh intersection), and a “three-dimensional intersection” ”(A three-dimensional stitch intersection).

  The “mesh part” includes the “penetrating part” (mesh-like transmission part) formed as a gap in a flat sheet material, and the “knitting part” (the mesh-like transmission part) formed as a gap by knitting an arbitrary fiber material. ).

  The “intersection” includes the “plane intersection” (planar mesh intersection) configured on a flat sheet material and the “three-dimensional intersection” (three-dimensional stitch) configured by knitting an arbitrary fiber material. Intersection).

  The “band-like fiber portion” refers to a fiber portion that connects the above-mentioned “intersection portions” adjacent to each other and includes the above-described “intersection portion” and is continuous in a band shape.

  In the golf club shaft according to the present invention, a mesh member made of a carbon fiber reinforced plastic material (for example, a triaxial woven fabric or a four-axial woven fabric mesh) fixed in the circumferential direction on the grip attachment end side of the steel shaft main body. Sheet material or mesh-like carbon fiber reinforced plastic material formed by directly winding a fiber material made of carbon fiber reinforced plastic around the shaft main body by the filament winding method, or fiber shaft made of carbon fiber reinforced plastic by the braiding method. The grip can be fixed to the outer periphery of mesh-like carbon fiber reinforced plastic material that is knitted directly on the main body, etc., so that the strength of the grip part, especially bending strength and flatness strength, etc. by the mesh member can be improved. The effect of weight reduction caused by the above, it is possible to obtain the like improve the vibration damping characteristics. In addition, the mesh member is knitted in various forms, such as a six-knit braid, so that it is possible to further improve the strength of the golf club shaft, as well as the weight of the golf club shaft. Can be realized. That is, it is possible to obtain an ultralight golf club shaft that has been difficult to realize with a conventional shaft body made of a single metal. Specifically, an ultra-light shaft of 80 grams or less having a strength required as a golf club shaft can be manufactured by reinforcement with a mesh member having a weight of about 2 to 10 grams.

  Furthermore, the grip can be securely fixed to the shaft main body by the frictional action or resistance action by the concavo-convex part (the mesh part and the intersecting part, and the belt-like fiber part) of the mesh member. Accordingly, it is possible to make the fixability of the grip as uniform as possible by an operator in the process of bonding or fixing the grip to the shaft body.

  In addition, if a part of the mesh member is exposed to the club head side from the grip, the ground color of the shaft body can be seen through the mesh part, so the design of this mesh part and the plating on the shaft body can be made. The appearance can be differentiated by coloring (such as the steel ground color itself).

  The steel shaft body is tenacious and can bend greatly compared to the carbon shaft (strong against large deflection), and is resistant to torsion (small torque angle and low torque), and scratches on the surface. There are advantages such as being difficult to attach.

  In the present invention, since the grip is attached to the steel shaft body through the mesh member made of carbon fiber reinforced plastic material having a mesh shape (or knitted shape) or other shape, the bending strength of the grip portion, In addition to improving flatness strength and vibration damping, it has improved grip fixability and realized an ultra-lightweight golf club shaft that can be differentiated in appearance.

  Next, a golf club 1 using a golf club shaft according to a first embodiment of the present invention will be described with reference to FIGS.

  FIG. 1 is a front view of a golf club 1, and the golf club 1 has a golf club shunt 2, a grip 3, and a club head 4.

  The golf club shaft 2 includes a shaft body 5 and a mesh sheet material 6 (mesh member).

  The shaft body 5 is made of steel, and the grip 3 can be attached to the grip attachment end 7 at one end, and the club head 4 can be attached to the club head attachment end 8 at the other end. To do.

  The mesh sheet material 6 has an axial length from the shaft body end 5A to the club head 4 side on the grip attachment end 7 side of the shaft body 5 until it is exposed from the grip 3, and in the circumferential direction thereof. This is continuously fixed once, and the grip 3 can be fixed to the outer peripheral side of the mesh sheet material 6. The annular exposed portion 6 </ b> A of the mesh sheet material 6 has a mesh-like or uneven appearance.

  The mesh sheet material 6 can be provided over a predetermined axial length within 600 mm from the shaft body end 5A.

  As a fixing mode of the mesh sheet material 6, in particular for the purpose of differentiating the appearance of the golf club shaft 2 itself, it is not only continuous in the circumferential direction or axial direction of the shaft body 5 but also discontinuous or It may be intermittent. However, in order to improve the bending strength, flatness strength, vibration damping property, etc. of the shaft main body portion and to reduce the weight, it is desirable to fix the shaft main body 5 in the circumferential direction once.

  The mesh sheet material 6 can employ a carbon fiber reinforced plastic material or a prepreg thereof. The prepreg is a material in which a carbon fiber or other fiber material (extra fine yarn called “open fiber”) is impregnated with a resin in advance, and the resin is cured by heating and bonded to the shaft body 5. it can. The number of “opened yarns” is 1000 to 3000 (1K to 3K), and the twisted yarn can be impregnated with resin.

  More specifically, the mesh sheet material 6 can be composed of a member having a mesh-like belt-like fiber portion 9 and a mesh-like transmission portion 10 (mesh portion) between the belt-like fiber portions 9.

  More preferably, the mesh sheet material 6 is formed by knitting the band-like fiber portion 9 as a fiber material such as a carbon fiber reinforced plastic material by “six stitch” (or “triaxial round weave”). Is desirable.

  Furthermore, regardless of whether the mesh sheet material 6 is formed of a flat sheet material or a fiber material so that the crossing portion is three-dimensional, it extends at least linearly in one stitch direction of the mesh sheet material 6. The flat strength can be improved by aligning a row of one fiber material (band-like fiber portion 9) in the circumferential direction of the shaft body 5, and the row of the fiber material (band-like fiber portion 9) can be used as a shaft. If the main body 5 is oriented in the axial direction, the bending strength can be improved. Furthermore, by orienting the row of the fiber material (band-like fiber portion 9) at an arbitrary angle with respect to the axial direction of the shaft body 5, the strength or vibration damping property can be adjusted appropriately.

  As the mesh shape of the mesh sheet material 6, any shape such as hexagon, pentagon, square, other quadrangle, rhombus, triangle, or circle, or a combination thereof can be adopted.

  For example, FIG. 2 is a plan view showing an example of a mesh sheet material 6 having a regular hexagonal shape and a triangular mesh shape, and “six-knit knitting” using a band-like fiber portion 9 made of a carbon fiber reinforced plastic material as a fiber material. And a relatively large regular hexagonal shape and a relatively small regular triangular mesh-like transmission part 10 are formed between the belt-like fiber parts 9. This belt-like fiber portion 9 having a predetermined thickness and its intersecting portion 11 become convex portions, and the mesh-like transmission portion 10 becomes a concave portion.

  As shown in FIG. 2, the “six stitch” is a crossing portion 11 when knitting a fiber material (band-like fiber portion 9) extending in three directions (triaxial directions) at an intersecting angle of 120 degrees into a hexagonal shape. The fiber material that intersects with each other is knitted so as to have a so-called three-dimensional intersection 11 such that the upper and lower positions of the adjacent intersection 11 are alternately repeated.

  The mesh sheet material 6 has, as the uneven shape or the roughness of the mesh, 1 to 30 concave portions or convex portions, in the illustrated example, concave portions (mesh-like transmission portion 10, mesh portion) per 1 square cm. Can be adopted.

  As the mesh sheet material 6, one having a diameter of 0.5 to 10 mm can be employed as the diameter of the circumscribed circle of the concave and convex portion, in the illustrated example, the concave portion (mesh-like transmission portion 10). For example, as shown in FIG. 2, the diameter of the regular hexagon circumscribed circle C1 is 2 mm, for example, and the diameter of the regular triangle circumscribed circle C2 is 1 mm, for example.

  FIG. 3 is a plan view showing another example of the mesh sheet material 6 having a regular hexagonal mesh shape. In this mesh sheet material 6, the width of the belt-like fiber portion 9 is increased to be a convex portion. The area occupied by the band-like fiber part 9 and the crossing part 11 is increased, and the hexagonal mesh-like transmission part 10 as a concave part is formed small. The diameter of the regular hexagonal circumscribed circle C3 is, for example, 1.5 mm. The diameter of the circumscribed circle C2 of the equilateral triangle is practically zero.

  As the mesh sheet material 6, one having a width of the band-like fiber portion 9 of 0.2 to 5 mm can be adopted. For example, the width of what is shown in FIG. 3 is 1 mm.

  In addition, the mesh sheet material 6 can make the thickness of the strip | belt-shaped fiber part 9 0.05-0.50 mm.

Moreover, the mesh sheet material 6 can make the weight 80-240 g / m < ² >.

  FIG. 4 is a plan view showing an example of a mesh sheet material 6 having a regular tetragonal mesh shape. The mesh sheet material 6 has a square mesh-shaped transmission portion 10 by knitting the belt-like fiber portions 9 of the mesh sheet material 6 in a perpendicular direction. Is forming.

  FIG. 5 is a plan view showing an example of a mesh sheet material 6 having a regular triangular mesh shape, and is obtained by knitting the belt-like fiber portion 9 of the mesh sheet material 6 at an angle of 60 degrees. Part 10 is formed.

  6 and 7 are explanatory views showing a process of attaching the mesh sheet material 6 and the grip 3 to the shaft body 5.

  That is, FIG. 6 is a main part front view showing a process of attaching the mesh sheet material 6 such as prepreg to the shaft body 5, and the mesh sheet material 6 is attached to the outer peripheral side of the grip attachment end portion 7 of the shaft body 5. Wrap around the circumference.

  As shown in a partially enlarged view in FIG. 6, the mesh sheet material 6 is temporarily fixed to the shaft body 5 by winding a belt-shaped synthetic resin tape 12 from the outer peripheral side at a predetermined pitch. In addition, an arbitrary adhesive may be applied to the outer surface of the shaft body 5 to temporarily fix the mesh sheet material 6.

  In this temporarily fixed state, the mesh sheet material 6 is fixed to the grip attachment end portion 7 of the shaft body 5 by heating to a predetermined temperature in the heating furnace 13. After the fixing, the synthetic resin tape 12 is removed, and the ground color of the shaft body 5 is made visible through the mesh-like transmission part 10.

  FIG. 7 is a cross-sectional view of the main part showing the step of attaching the grip 3 to the shaft body 5 covered with the mesh sheet material 6, and the adhesive 14 is applied to the outer peripheral side of the mesh sheet material 6.

  A rubber grip 3 inflated with air pressure from the inside is covered from the outer peripheral side, and by releasing the expansion of the grip 3, the grip 3 is returned to the original shape and bonded and fixed to the grip attachment end portion 7, as shown in FIG. Can be attached to the state shown.

  Since the grip 3 is bonded to the grip attachment end portion 7 of the shaft body 5 via the mesh sheet material 6, the grip 3 is firmly fixed by the frictional action with the mesh sheet material 6, and the attached state is fixed. Sex can be secured.

  In particular, as shown in FIG. 1, by exposing a part of the mesh sheet material 6 (exposed portion 6A) from the grip 3 to the club head 4 side, a characteristic design of the mesh sheet material 6 is expressed, Appearance distinguishing characteristics can be exhibited.

  That is, when the mesh shape of the belt-like fiber portion 9 to the mesh-like transmission portion 10 in the mesh sheet material 6 is a hexagonal shape, pentagonal shape, quadrangular shape, rhombus shape, triangular shape, circular shape, or other specific pattern, When the portion 9 is made of a carbon fiber reinforced plastic material, the black color can be reflected on the steel shaft body 5 to obtain a unique appearance feature.

  That is, if the ground color (silver color or silver white color) of the shaft body 5 can be visually recognized through the mesh-like transmission part 10, differentiation in appearance can be achieved.

  Further, if the shaft main body 5 is colored in an arbitrary color (for example, red, orange, yellow, green, blue, purple, or other colors by plating or the like) in a color that can be visually recognized through the mesh-shaped transmission portion 10, the design is further improved. Can be rich in types.

  FIG. 8 is a front view showing a configuration example when the golf club 1 is set as a wood, an iron, and a putter. For example, the golf club 1 is set on a portion (exposed portion 6A) exposed from the grip 3. It can comprise so that the mesh sheet | seat material 6 which has a common design may be provided.

  In addition, the golf sheet 1 with different counts can be designed by changing the tone of the design of the mesh sheet material 6 or the ground color of the shaft body 5 that can be visually recognized through the mesh-like transmission part 10 or changing the tone in sequence. Thus, the golfer can increase the width when the club shaft 1 is selected or used.

  Further, since the mesh sheet material 6 is additionally attached to the grip 3 portion, the rigidity of this portion is increased, and the bending strength, flatness strength, vibration damping property, etc. of the shaft body 5 portion to which the grip 3 is fixed are increased. As a result, the golf club 1 can be reduced in weight while being able to improve strength, and favorable characteristics can be obtained.

  In particular, the belt-like fiber portion 9 is knitted by “six stitch” as a fiber material such as a carbon fiber reinforced plastic material, and at least one fiber material (band-like fiber portion) linearly extending in one stitch direction in the mesh sheet material 6. By positioning the row 9) at a predetermined orientation angle with respect to the circumferential direction or the axial direction of the shaft body 5, the bending strength, flatness strength, vibration damping property, etc. of the shaft body 5 can be improved. .

  For example, a case where a mesh sheet material 6 made of a prepreg made of a carbon fiber reinforced plastic material as shown in FIG. 3 is wound around and fixed to a steel shaft body 5 will be described.

  FIG. 9 is a perspective view of the first test piece 20 having a length of 50 mm by the shaft body 5 of the grip 3 portion for performing a flat strength test, and FIG. 10 is the same length by the shaft body 5 of the grip 3 portion. It is a perspective view of the 2nd test piece 21 of 50 mm.

  The first test piece 20 is a conventional steel shaft main body 5 (base tube), and the second test piece 21 fixes the mesh sheet material 6 to the shaft main body 5 from the shaft main body end 5A to a length of 40 mm. In accordance with the present invention. In addition, about the 2nd test piece 21, what coated the mesh sheet material 6 1 sheet and 2 sheets was prepared.

  However, in the mesh sheet material 6, a row of fiber materials (band-like fiber portions 9) linearly extending in at least one direction is oriented in the circumferential direction of the shaft body 5.

  The first test piece 20 and the second test piece 21 both have an outer diameter of 14.80 mm and a wall thickness of 0.288 mm. The width of the fiber material (band-like fiber portion 9) of the mesh sheet material 6 is 1 mm, and the thickness is 0.07 mm.

  FIG. 11 is a schematic side view of the flat strength test apparatus 22 of the first test piece 20 and the second test piece 21. The flat strength test apparatus 22 includes a metal cradle 23 and a metal A first test piece 20 and a second test piece 21 that have an indenter 24, a pressing part 25, and a load measuring part 26 and are set between the cradle 23 and the indenter 24 are pressed by the pressing part 25. A load was continuously applied until the first test piece 20 and the second test piece 21 were broken at a pressing speed of 24, that is, a load speed of 5 mm / min, and the load at the time of breakage was measured by the load measuring unit 26.

  FIG. 12 is a graph showing the test results of flat strength, and in the case of the first test piece 20 not covering the mesh sheet material 6, it was broken with a load of 70 kgf. The second test piece 21 covered with one mesh sheet material 6 was broken at a load of 80 kgf. The second test piece 21 covered with two mesh sheet materials 6 was broken with a load of 82 kgf.

  That is, when the mesh sheet material 6 having the sixth stitch structure is wound around the shaft body 5, the flat strength is improved by 14%, and when it is wound twice, an improvement of 17% can be confirmed. .

Next, the bending strength was also tested.
FIG. 13 is a schematic side view of the three-point bending strength test apparatus 30. The three-point bending strength test apparatus 30 includes a pair of left and right support parts 31, a load part 32, and a load measurement part 33. 9 and FIG. 10 (provided that the length is 300 mm or more) and load the central portion of the first test piece 20 or the second test piece 21 (a portion of 175 mm from the shaft main body end 5A). The measurement unit 33 continued to apply a load until the first test piece 20 and the second test piece 21 were broken at a load speed, that is, a load speed of 20 mm / min, and the load measurement unit 33 measured the load at the time of the break.

  As a result of the measurement, in the case of the first test piece 20 not covering the mesh sheet material 6, it was broken with a load of 40.6 kgf. The second test piece 21 covered with one mesh sheet material 6 was broken with a load of 46.2 kgf. That is, it was confirmed that the bending strength was improved by 13.8% when the mesh sheet material 6 having the sixth stitch structure was wound once around the shaft body 5.

Next, the Izod impact value was also tested.
FIG. 14 is a schematic side view of the test apparatus 40 for Izod impact value. The test apparatus 40 for Izod impact value includes a base part 41, a piece fixing part 42 arranged at the center part thereof, a frame part 43, It has a rotation shaft 44, an arm portion 45 that can rotate around the rotation shaft 4, a hammer 46 fixed to the tip of the arm portion 45, and an impact value measurement portion 47.

  The first test piece 20 and the first test piece 20 and the first test piece 20 prepared in the same manner as in FIG. 9 and FIG. The impact at the time of destruction was measured by the impact value measuring unit 47 by colliding with the second test piece 21.

  As a result of the measurement, the first test piece 20 not covering the mesh sheet material 6 was broken at an impact strength of 9.1 ft-lb (feet lb). The second test piece 21 covered with one mesh sheet material 6 was broken at an impact strength of 9.9 ft-lb (feet lb). That is, it was confirmed that the Izod impact value was improved by 8.8% when the mesh sheet material 6 having the sixth stitch structure was wound once around the shaft body 5.

Next, vibration damping was also tested. This test is called an impact response test or a transfer function measurement test.
FIG. 15 is a schematic side view of the vibration damping test apparatus 50, which is a steel shaft body 5 (element tube) around which the mesh sheet material 6 is not wound and a steel shaft body around which the mesh sheet 6 is wound. 51 is shown. In addition, the length of the shaft main bodies 5 and 51 is set to L, and the mesh sheet material 6 is fixed to the shaft main body 51 from the shaft main body end 51A to a site of 400 mm.

  The vibration damping test device 50 includes a pair of support points 52 provided by hanging a thread at a portion 0.224 · L from the respective ends on the grip side and the head side, an impulse hammer 53, and a grip end. , And an accelerometer 54 attached at a position 150 mm away from the head, and the accelerometer 54 measures the acceleration according to the impact of the impulse hammer 53 on the position of the support point 52.

  The measuring instrument used was an impulse hammer kit manufactured by PCB, and the analyzer used was an Ono Sokki FFT analyzer. The test condition is the acceleration (output A) with respect to the impact (input F) by the impulse hammer 53, and the frequency response function = A / F is obtained from this. As analysis conditions, the average number of times is 20, the maximum frequency is 2.5 KHz (ΔF), and the resolution is 4096 (N).

  FIG. 16 is a graph showing the relationship of the frequency response function with respect to the frequency. In the figure, the dotted line represents the case of the shaft body 5 made of a raw pipe, and the solid line represents the case of the shaft body 51 with the mesh sheet material 6 according to the present invention. Each is shown.

  As shown in the figure, regarding the shaft body 51 with the mesh sheet material 6, the value of the frequency response function is decreased particularly on the high frequency side having a large influence on the vibration at the time of hitting, and the vibration damping characteristics are improved.

  FIG. 17 is a chart showing the difference between the value of the frequency response function of the shaft body 5 by the blank tube and the value of the frequency response function of the shaft body 51 with the mesh sheet material 6 at a specific frequency, each of which is significant. It can be seen that there is a difference.

  Next, the mesh member in the present invention is not limited to the mesh sheet material 6 as described above, and the fiber material is directly wound around the outer peripheral surface of the grip attachment end portion 7 of the shaft body 5, thereby It can also be configured to form a mesh-like member.

  For example, FIG. 18 is a front view of the main part of the grip mounting end portion 7 portion of the golf club shaft 60 according to the second embodiment of the present invention. The golf club shaft 60 is made of a fiber material 61 (carbon fiber reinforced plastic). A mesh-like carbon fiber reinforced plastic material 62 constituted by winding a predetermined number, for example, two in the drawing, directly and spirally around the shaft body 5 at a predetermined orientation angle by a filament winding method is fixed as a mesh member. The mesh-like carbon fiber reinforced plastic material 62 has a rhombic mesh shape.

  A fiber material 61 made of carbon fiber reinforced plastic is a fiber material obtained by previously impregnating a carbon fiber or other fiber material (extra fine yarn called “open fiber”) with a resin. The number can be 1000 to 3000 (1K to 3K).

  The fiber material 61 made of carbon fiber reinforced plastic can have a thickness of 0.05 to 0.3 mm, for example 0.07 mm, and a width of 0.2 to 5 mm, for example 3 mm. 6 in the same manner as the belt-like fiber portion 9 in FIG.

  Further, the mesh-like carbon fiber reinforced plastic material 62 can also be configured to have the mesh-like belt-like fiber portion 9 and the mesh-like transmission portion 10 similar to the mesh sheet material 6.

  Also in the golf club shaft 60 having such a configuration, in the same way as the golf club shaft 2 shown in FIG. 1, the bending strength, flatness strength, vibration damping property, etc. are improved, and the fixability of the grip 3 is improved. Can also be differentiated.

  Next, FIG. 19 is a front view of an essential part of the grip mounting end portion 7 portion of the golf club shaft 70 according to the third embodiment of the present invention. The golf club shaft 70 is the golf club shaft shown in FIG. Similarly to the mesh-like carbon fiber reinforced plastic material 62 in 60, the mesh-like carbon fiber reinforced plastic material 71 formed by directly knitting the fiber material 61 made of carbon fiber-reinforced plastic on the shaft body 5 in various patterns by the braiding method is meshed. It is fixed as a member. The mesh-like carbon fiber reinforced plastic material 71 has a rhombus or square mesh shape.

  In the golf club shaft 70 having such a configuration, the bending strength, the flat strength, the vibration damping property, and the like are improved similarly to the golf club shaft 2 shown in FIG. 1 or the golf club shaft 60 shown in FIG. The fixability of the grip 3 can be improved and the appearance can be differentiated.

Next, another example of the mesh material (mesh sheet material) in the present invention will be described.
FIG. 20 is a plan view of a mesh sheet material 80 made of a four-axis woven fabric, and the mesh sheet material 80 is a fiber like the mesh sheet material 6 made of a tri-axial woven fabric (see FIGS. 2 and 3). A material (band-like fiber part 9) is knitted in three dimensions to constitute this.

  The mesh sheet material 80 has a row of strip-like fiber portions 9 extending linearly in four different directions. That is, the mesh sheet material 80 includes a row 9A of strip-like fiber portions 9 oriented in the axial direction of the shaft body 5, a row 9B of strip-like fiber portions 9 oriented in the circumferential direction of the shaft body 5, and the axis of the shaft body 5. The direction and the circumferential direction have two rows 9C and 9D of strip-like fiber portions 9 that are oriented at an inclination angle of 45 degrees and are orthogonal to each other.

  The width and thickness of the belt-like fiber portion 9 can be selected in the same manner as in the case of the mesh sheet material 6 (FIG. 3). In the illustrated example, the width and thickness are 1 mm, and between the row 9A and the row 9B. The pitch is 3.2 mm, and the pitch between the rows 9C and 9D is 4.5 mm, and is three-dimensionally knitted as shown in the figure.

  In addition, the mesh part (mesh-like transmission part 10) of the mesh sheet material 80 has a pentagonal shape, and the diameter of the circumscribed circle C4 is, for example, 2.3 mm.

  For the mesh sheet material 80 having such a configuration, the same strength test as that of the mesh sheet material 6 was performed.

  That is, a mesh sheet material 80 made of a prepreg made of carbon fiber reinforced plastic material was wound around a steel shaft body 5 and fixed, and the same flat strength test as described with reference to FIGS. 9 to 12 was performed.

  Furthermore, the same three-point bending strength test as described with reference to FIG. 13 was performed.

  Moreover, the test about the Izod impact value similar to what was demonstrated based on FIG. 14 was done.

  FIG. 21 shows the experimental results of the flat strength, the three-point bending strength, and the Izod impact value in the case of the shaft alone and in the case of the shaft body 5 (four-axis composite) wound with the mesh sheet material 80 according to the present invention. It is a chart. In the figure, the N number indicates the number of samples, and the numerical values for the flattening strength, the three-point bending strength, and the Izod impact value indicate the average value of the number of samples.

  As shown, the weight difference is about 15%, 24%, and 48% for flat strength, three-point bending strength, and Izod impact value, respectively, despite an increase of 2.8 grams (3.7%). Can be realized.

  Further, as a result of the same vibration damping test as described with reference to FIGS. 15 to 17, vibration damping equivalent to that of the triaxial composite mesh sheet material 6 (FIG. 3) can be obtained. It was.

  Thus, the golf club shafts 1, 60, and 70 are required by slightly reinforcing the weight material with mesh members such as the mesh sheet materials 6 and 80 having a weight of about 2 to 10 grams or the mesh-like carbon fiber reinforced plastic materials 62 and 71. Super lightweight shaft (golf club shafts 1, 60, 70) that has flat strength and bending strength that can withstand use even when the weight of the shaft body 5 is 80 grams or less. Can be manufactured.

1 is a front view of a golf club using a golf club shaft according to a first embodiment of the present invention. It is a top view which shows an example of the mesh sheet material which has a regular hexagon shape and a triangular mesh shape. It is a top view which shows the other example of the mesh sheet material which has a regular hexagonal mesh shape. It is a top view which shows an example of the mesh sheet material which has a square shape of a regular tetragon. It is a top view which shows an example of the mesh sheet | seat material which has a regular triangular mesh shape. It is a principal part front view which shows the process of attaching a mesh sheet material to a shaft main body. It is principal part sectional drawing which shows the process of attaching a grip to the shaft main body which covered the mesh sheet material similarly. FIG. 3 is a front view showing a configuration example when the golf club is set as a wood, an iron, and a putter. It is a perspective view of the 1st test piece of length 50mm by the shaft main body of the grip part for testing flat strength. It is a perspective view of the 2nd test piece of length 50mm by the shaft main body of a grip part similarly. It is a schematic side view of the flat strength test apparatus. It is a graph which shows the test result of flat strength similarly. It is a schematic side view of a three-point bending strength test apparatus. It is a schematic side view of the test apparatus of an Izod impact value. It is a schematic side view of a vibration damping test device. It is a graph which shows the relationship of the frequency response function with respect to a frequency similarly. It is a chart showing the difference of the value of the frequency response function of the shaft main body by a raw pipe and the value of the frequency response function of the shaft main body with a mesh sheet material in a specific frequency. It is a principal part front view of the grip attachment edge part part of the golf club shaft by the 2nd Example of this invention. It is a principal part front view of the grip attachment edge part of the golf club shaft by the 3rd Example of this invention. It is a top view of the other example (mesh sheet material by a four-axis direction textile fabric) in the present invention. FIG. 6 is a chart of experimental results for flat strength, three-point bending strength, and Izod impact value in the case of a single shaft and a shaft main body (four-axis composite) wound with a mesh sheet material according to the present invention.

Explanation of symbols

1 Golf club (Figure 1)
2 Golf club shaft (first embodiment, FIG. 1)
3 grip 4 club head 5 shaft body 5A made of steel shaft body end 6 of shaft body 5 mesh sheet material (mesh member)
6A An annular exposed portion 7 of the mesh sheet material 6 Grip attachment end portion 8 of the shaft body 5 Club head attachment end portion 9 of the shaft body 5 Band-like fiber portions (fiber materials) of the mesh sheet materials 6 and 80
9A A row of strip-like fiber portions 9 oriented in the axial direction of the shaft body 5 (FIG. 20)
9B A row of strip-like fiber portions 9 oriented in the circumferential direction of the shaft body 5 (FIG. 20)
9C, 9D Two rows of strip-like fiber portions 9 that are oriented at an inclination angle of 45 degrees with respect to the axial direction and the circumferential direction of the shaft body 5 (FIG. 20)
10 Mesh transmission material (mesh part) of mesh sheet materials 6 and 80
11 Crossing portion 12 of belt-like fiber portion 9 Synthetic resin tape (FIG. 6)
13 Heating furnace (Fig. 6)
14 Adhesive (Figure 7)
20 First test piece (conventional, FIG. 9)
21 Second test piece (present invention, FIG. 10)
22 Flat strength test equipment (Figure 11)
23 cradle 24 indenter 25 pressing part 26 load measuring part 30 three-point bending strength test device (FIG. 13)
31 A pair of left and right support portions 32 Load portion 33 Load measurement portion 40 Izod impact value test device (FIG. 14)
41 Base part 42 Piece fixing part 43 Frame part 44 Rotating shaft 45 Arm part 46 Hammer 47 Impact value measuring part 50 Vibration damping test device (FIG. 15)
51 Steel shaft body 51A around which mesh sheet 6 is wound 51A Shaft body end 52 of shaft body 51 A pair of supporting points 53 Impulse hammer 54 Accelerometer 60 Golf club shaft (second embodiment, FIG. 18)
61 Fiber material made of carbon fiber reinforced plastic 62 Mesh carbon fiber reinforced plastic material (mesh member)
70 golf club shaft (third embodiment, FIG. 19)
71 Mesh-like carbon fiber reinforced plastic material (mesh member)
80 Mesh sheet material (mesh member) (Fig. 20)
C1 Regular hexagonal circumscribed circle of the mesh-like transmission part 10 (FIG. 2)
C2 A regular triangular circumscribed circle of the mesh-like transmission part 10 (FIG. 2)
C3 Regular hexagonal circumscribed circle of the mesh-like transmission part 10 (FIG. 3)
C4 pentagon circumscribed circle of mesh-like transmission part 10 (FIG. 20)
L Length of shaft body 5, 51 (Fig. 15)

Claims (21)

A golf club shaft having a steel shaft body to which a grip is attached at one end and a club head is attached at the other end,
While fixing the mesh member composed of carbon fiber reinforced plastic material in the circumferential direction on the outer peripheral side on the grip mounting end side of the shaft body,
A golf club shaft characterized in that the grip can be fixed to the outer peripheral side of the mesh member.   The golf club shaft according to claim 1, wherein the mesh member is a mesh sheet material formed by knitting a fiber material into a sheet shape.   2. The golf club shaft according to claim 1, wherein the mesh member is a mesh-like carbon fiber reinforced plastic material formed by winding a fiber material made of carbon fiber reinforced plastic directly around the shaft body by a filament winding method.   2. The golf club shaft according to claim 1, wherein the mesh member is a mesh-like carbon fiber reinforced plastic material formed by directly winding a fiber material made of carbon fiber reinforced plastic on the shaft body by a braiding method. The mesh member is configured by knitting a fiber material,
The golf club shaft according to claim 1, wherein the mesh member has a row of the fiber material extending linearly in at least one direction oriented in a circumferential direction of the shaft body. The mesh member is configured by knitting a fiber material,
2. The golf club shaft according to claim 1, wherein the row of the fiber material extending linearly in at least one direction in the mesh member is oriented in the axial direction of the shaft body. The mesh member is configured by knitting a fiber material,
2. The golf club shaft according to claim 1, wherein the row of the fiber material extending linearly in at least one direction in the mesh member is oriented at an arbitrary angle with respect to the axial direction of the shaft body. The mesh member is configured by knitting a fiber material,
2. The golf club shaft according to claim 1, wherein the mesh member has a row of the fiber material extending linearly in three different directions. The mesh member is configured by knitting a fiber material,
2. The golf club shaft according to claim 1, further comprising a row of the fiber material extending linearly in four different directions from each other in the mesh member. The mesh member is configured by knitting a fiber material,
A row of the fibrous material oriented in the axial direction of the shaft body;
A row of the fibrous material oriented in a circumferential direction of the shaft body;
The golf club shaft according to claim 1, comprising: two rows of the fiber material oriented at an inclination angle of 45 degrees with respect to the axial direction and the circumferential direction of the shaft main body and orthogonal to each other.   2. The golf club shaft according to claim 1, wherein the mesh member is formed by knitting a fiber material by a sixth stitch.   2. The golf club shaft according to claim 1, wherein the mesh member is formed so as to form a hexagonal stitch by knitting a fiber material.   2. The golf club shaft according to claim 1, wherein the mesh member is formed so as to form a pentagonal stitch by knitting a fiber material.   2. The golf club shaft according to claim 1, wherein the mesh member is formed by knitting a fiber material made of prepreg. The mesh member is constituted by a member having a mesh-like belt-like fiber portion and a mesh portion between the belt-like fiber portions, and is exposed to the club head side from the grip,
2. The golf club shaft according to claim 1, wherein the ground color of the shaft main body is visible through the mesh portion. The mesh member is constituted by a member having a mesh-like belt-like fiber portion and a mesh portion between the belt-like fiber portions, and is exposed to the club head side from the grip,
2. The golf club shaft according to claim 1, wherein the shaft body is colored in a color that can be visually recognized through the mesh portion of the mesh member.   2. The golf club shaft according to claim 1, wherein the mesh member has 1 to 30 meshes or intersections per square centimeter as the mesh roughness.   The golf club shaft according to claim 1, wherein a diameter of a circumscribed circle of the mesh portion of the mesh member is 0.5 to 10 mm. The mesh member is configured by knitting a fiber material,
The golf club shaft according to claim 1, wherein the fiber material has a width of 0.2 to 5 mm. The mesh member is configured by knitting a fiber material,
2. The golf club shaft according to claim 1, wherein a thickness of the fiber material is 0.05 to 0.50 mm. The golf club shaft according to claim 1, wherein the mesh member has a weight of 80 to 240 g / m ² .

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