KR100803528B1 - Golf ball - Google Patents

Abstract

A golf ball is provided to make air resistance identical to or smaller than that of a dimple golf ball by forming grooves in a net shape on the surface of a spherical surface thereof. Grooves(20) in a net shape are formed on the spherical body(10) of a golf ball. The area of the grooves is 14 to 69% of the surface area of the golf ball. The width of the groove is 1 to 5mm, and the depth of the groove is 0.1 to 0.5mm. Protrusions having a height that is smaller than the depth of the groove are formed on the groove. The grooves in a net shape are connected to each other or cut off from each other in the middle thereof. The protrusions are connected to each other or are cut off from each other.

Description

Golf ball {Golf ball}

Figure 1a is a perspective view showing a dimple golf ball when putting.

FIG. 1B is a cross-sectional view taken along the line A-A of FIG. 1A.

Figure 2 is a plan view showing a grooved golf ball according to an embodiment of the present invention.

Figure 3 is a schematic diagram showing an embodiment of forming a groove according to the present invention.

4 is a schematic view showing another embodiment of forming a groove according to the present invention.

Figure 5 is a plan view showing another embodiment of forming a groove according to the present invention.

6 is a photograph showing an experimental apparatus in which a model according to the present invention is installed.

Figure 7 is a schematic diagram showing a process of forming a groove on the model surface according to the present invention.

8 is a photograph showing a model in which a groove is formed according to the present invention and a protrusion formed in the middle of the groove is broken.

9A and 11A are graphs showing Reynolds number versus drag coefficient.

9B and 11B are graphs showing golf ball speed versus air resistance.

10 is a photograph showing another model in which grooves are formed and protrusions are formed on the grooves according to the present invention.

12 is a view showing a partial cross-section of the golf ball is formed with a groove according to the present invention is a projection formed on the groove.

<Explanation of symbols for the main parts of the drawings>

10: sphere 20: groove

21: projection θ: included angle

The present invention relates to a golf ball, which has air resistance similar to or smaller than that of a dimple golf ball, while at the same time significantly reducing the area ratio of the groove to the golf ball surface area, thereby improving the distance and correct directionality when putting. It is about a golf ball to have.

In general, golf balls having circular dimples arranged on the surface by dividing the surface of the sphere into spherical polyhedrons have been used for a long time. Dimple golf balls satisfy the spherical symmetry and at the same time reduce the air resistance to increase the flying distance.

In addition, as the dividing composition of the sphere, the most widely used are spherical icosahedron, spherical 20-12 polyhedron, spherical dodecahedron, spherical octahedron, spherical hexahedron, spherical 6-8 octahedron or the like In fact, in the golf ball of the same size in addition to the modified specifically in the above-described divided composition, since the above-mentioned divided compositions can overlap each other, all of them can be interpreted as the same composition. If circular dimples are arranged on the divided composition, the distance of the golf ball will be determined mainly by the area ratio of the dimple to the golf ball surface area.

When the golfer hits the dimple golf ball, the force applied from the golf club head causes a strong resilience to the golf ball and at the same time, a reverse rotation occurs due to the loft angle of the club head. It will bounce off at an initial speed of about 190 to 300 km / hr and have an initial reverse of about 2200 to 4500 rpm. At this time, the dimple generates turbulence at the golf ball surface, and the generated turbulence delays the flow separation, thereby reducing the pressure difference between the front and back of the dimple golf ball, thereby reducing the air resistance.

Contrary to the existing hypothesis that the air flowing into the dimple vortexes to cause turbulence for dimple golf balls, the inventors of the present application describe the "air" in the April 2006 issue of the journal Physics of Fluids. Experiments prove that turbulence is generated because it does not enter the dimple but floats in the air and becomes unstable. ”

However, in order to induce a decrease in air resistance in the dimple golf ball, the area ratio occupied by the dimple with respect to the surface area of the golf ball should generally be 75% or more.

As shown in Figure 1a and 1b, the area ratio occupied by the dimple in the dimple golf ball (1) is so large that the putter (2) during the putt hitting the curved surface on which the dimple of the golf ball is formed, the golfer intended The golf ball proceeds in a direction slightly off. That is, the golf ball misses the hole cup even if a very small angle error occurs when putting.

The present invention is to solve the above problems, through the net-shaped grooves formed on the surface of the sphere to improve the distance by increasing the air resistance similar to or smaller than the dimple golf ball while at the same time improving the area ratio of the groove to the golf ball surface area The aim is to provide a golf ball that is significantly reduced to have the correct orientation when putting.

In order to achieve the above object, the golf ball of the present invention, a groove-like groove is formed on the surface of the sphere, the groove area is 14 to 69% of the golf ball surface area, the groove width is 4 mm or less The depth of the groove is characterized in that 0.1 to 0.4mm. In addition, a net-shaped groove is formed on the surface of the sphere, the groove area is 14 to 69% of the golf ball surface area, the groove width is 1 to 5 mm, the depth of the groove is 0.1 to 0.5 mm, The groove may be formed with a projection at least a height lower than the depth of the groove.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Golf ball according to a preferred embodiment of the present invention, as shown in Figure 2 includes a groove (groove) 20 in the form of a mesh on the surface of the sphere (10). The grooves 20 of the mesh form may be interconnected or broken in the middle to prevent the grooves 20 from being formed.

Groove 20 can be transformed into various shapes as long as the mesh shape, and as shown in FIG. 3, the sphere 10 is divided into spherical regular polyhedrons, and the vertices 31 and spheres 10 of the spherical regular polygon constituting the spherical regular polyhedron. The included angle θ of the straight line 32 connecting the center 11 of the center 11 and the straight line 34 connecting the center 11 of the sphere 10 and the point 33a on the surface of the sphere 10 is a constant angle. A groove is formed along a circle 35 connecting the points 33a of the surface of the sphere 10 to be formed. A spherical regular polyhedron is a polyhedron having a line formed by placing a regular polyhedron inside the sphere so that the vertex 31 contacts the sphere and connecting two vertices 31 forming the corners of the regular polyhedron so that the shortest distance from the surface of the sphere is a corner. Means.

In this case, the spherical tetrahedron may be a spherical cube or a icosahedron, and the included angle θ may be 45 to 80 °. A spherical cube consists of six spherical squares and has eight vertices 31, and a spherical icosahedron consists of 20 spherical equilateral triangles and has twelve vertices 31, one around each vertex 31. Forming grooves shaped like a circle 35 to interconnect eight or twelve grooves on the surface of the sphere reduces the area ratio occupied by the grooves 20 relative to the surface area of the golf ball so that the golf ball is in the correct direction when putting. To help you progress. When the vertex 31 is a stagnation point, if the surface is a smooth sphere, flow separation occurs at an included angle θ near about 80 °, so that the groove 20 is used before the flow separation occurs. Delaying the peeling near 120 ° by generating a separation bubble can significantly reduce the air resistance received by the golf ball, and it is preferable to form a groove at an included angle θ of 45 to 80 °.

In addition, as shown in FIG. 4, the sphere 10 is divided into spherical regular polyhedrons, and a straight line 37 connecting the center of gravity of the spherical 10 and the center of gravity of the spherical regular polygon constituting the spherical regular polyhedron. And the points 33b on the surface of the sphere 10 in which the included angle θ of the straight line 38 connecting the center 11 of the sphere 10 and the point 33b on the surface of the sphere 10 becomes an angle. Grooves may be formed along the connected circle 39.

In this case, the spherical tetrahedron is preferably spherical octahedron or dodecahedron, and the included angle θ is preferably 45 to 80 °. The spherical octahedron consists of eight spherical equilateral triangles and has six vertices 31, and the spherical dodecahedron consists of twelve spherical pentagons and has twenty vertices 31. If one groove is formed to form six or twenty circle 39 grooves interconnected, the area ratio of the groove to the golf ball surface area becomes so small that the air resistance does not decrease as expected or the golf ball surface area. The area ratio occupied by the grooves on the can become so large that the directionality may be poor when putting.

In addition to the grooves formed as described above, if the groove is in the form of a mesh, and the groove satisfies spherical symmetry and the groove area occupies 14 to 69% of the golf ball surface area, various shape deformations of the groove are possible.

As another embodiment of the groove shape, the sphere 10 is partitioned into spherical polyhedra and grooves are formed along the edges 41 of the spherical polyhedron. At this time, the spherical polyhedron may be a spherical icosahedron or a spherical icosahedron composed of eight spherical pentagons and twelve spherical regular hexagons, as shown in FIG. 5, to form a dimple on the sphere 10. In the case of dividing the sphere into spherical polyhedrons so as to be spherical symmetrical, grooves may be formed along the edge 41 of the spherical polyhedron and thus may be applied to the present invention. In addition, grooves formed along the edges 41 of the spherical polyhedron may be interconnected or broken in the middle to prevent grooves from being formed.

As illustrated in FIG. 6, the model was installed in the wind tunnel, and the air resistance was measured by increasing the experimental wind speed from 5 kPa to 30 kPa in 1 kPa, and the model and the similarity were measured by dimensional analysis and similarity. If the Reynolds number of the golf ball is the same, each drag coefficient is also the same, so the experimental value can be used to convert the actual air resistance in the golf ball.

A method of forming a groove on the model surface used for the experiment will be described in detail with reference to FIG. 7 as follows. A circle (35a) that divides the model into a spherical cube by arranging the cube inscribed in the model and connects three vertices (31b, 31c, not shown) closest to one of the spherical squares 31a constituting the spherical cube. In this case, the included angle θ is about 70 °, and the circles 35b to 35h are displayed as described above at the remaining vertices 31b, 31c, 31d, and not shown, and the displayed circles 35a to 35h are shown. ) And grooves along the short diagonal lines 42a to 42d (not shown) of the cells in which the corners 41 of the spherical cube are located among the cells divided by the circles 35a to 35h. Form.

In addition, the diameter of the model is 150 mm, grooves having a width of 5 mm and a depth of 0.5 mm are formed on the surface of the model (Example 1), and protrusions having a height of 0.5 mm are formed on the grooves (Example 2) As shown in Fig. 8, the projections are broken in the middle and removed (Example 3).

Sphere diameter Width of groove Depth of groove Height of protrusion Example 1 42.67 mm 1.42 mm 0.142 mm · Example 2 42.67 mm 1.42 mm 0.142 mm 0.142 mm Example 3 42.67 mm 1.42 mm 0.142 mm 0.142 mm

Table 1 shows the converted values of the model and is regarded as the number of golf balls with grooves formed on the surface by dimensional analysis and similarity.

Figure 9a is a graph showing the drag coefficient according to the Reynolds number, Figure 9b is a graph showing the air resistance according to the speed of the golf ball, the air resistance of the conventional golf ball dimple formed and the grooved golf ball according to the present invention It is a comparison.

In the case of Example 1, it can be seen that the air resistance decreases more than the dimple golf ball from the Reynolds number 190000 (the speed of the golf ball 240 km / hr), and the dimple considering the initial speed of the drive shot is 190 to 300 km / hr. It is not suitable as a golf ball because the overall air resistance will increase rather than the golf ball and the distance of the golf ball will be relatively reduced. Therefore, when the width of the groove is smaller than 2 mm without protrusions, the air resistance increases compared to the dimple golf ball and the distance of the golf ball is reduced. Therefore, when the width of the grooves is smaller than 2 mm without protrusions, the grooves are smaller than those of the first embodiment. It may be desirable to increase the area ratio of the grooves to the golf ball surface area by forming a large number for reducing the air resistance.

On the other hand, in Example 2, in which the protrusions are formed in the grooves, except that the Reynolds number of 50000 (80km / hr) ~ 110000 (140km / hr) section, the overall air resistance of the grooved golf ball is further reduced compared to the dimple golf ball 9A and 9B, the dimple golf ball has only about 23% of the groove area relative to the golf ball surface area, considering that the dimple area ratio is about 75 to 84% of the golf ball surface area. The occurrence of errors due to the bending of the grooves is significantly reduced, enabling accurate putting.

The third embodiment is the same as the second embodiment, except that the projections formed in the grooves are not connected to each other but are broken in the middle. In the case of Example 3, it can be seen that the air resistance is further reduced as compared with the dimple golf ball as in Example 2.

The diameter of the other model used in the experiment was 150 mm, and grooves having a width of 10 mm and a depth of 1 mm were formed on the surface of the model (Example 4), and as shown in FIG. It is formed (Example 5).

Sphere diameter Width of groove Depth of groove Height of protrusion Example 4 42.67 mm 2.84 mm 0.284 mm · Example 5 42.67 mm 2.84 mm 0.284 mm 0.284 mm

Table 2 shows the conversion values of the different models, which are regarded as the number of golf balls with grooves formed on the surface by dimensional analysis and similarity.

Figure 11a is a graph showing the drag coefficient according to the Reynolds number, Figure 11b is a graph showing the air resistance according to the speed of the golf ball, the air resistance of the conventional golf ball dimple formed and the grooved golf ball according to the present invention It is a comparison.

Example 4 and Example 5 showed similar air resistance as dimple golf balls, but in the above example, the area ratio of the groove to the surface area of the golf ball was only about 46%, so that the putting was still more accurate than the dimple golf ball. It can be seen that.

When grooves are formed without protrusions, the width W of the grooves 20 should be 4 mm or less, and the depth GH of the grooves 20 should be 0.1 to 0.4 in consideration of the air resistance received by the golf ball and the correct direction when putting. It is preferable to set it to mm. This is because when the depth GH of the groove 20 is less than 0.1 mm, the reverse rotational speed of the golf ball is further reduced compared to the dimple golf ball, thereby reducing the lift force.

In addition, when the projection 21 is formed in the groove 20 as shown in FIG. 12, the width W of the groove 20 is 1-5 mm, and the depth GH of the groove 20 is The height H of the protrusions 21 is preferably smaller than the depth GH of the grooves 20, and the protrusions 21 are formed in the grooves 20. Likewise interconnected, but can be removed by breaking the projection 21 in the middle of the groove (20).

At this time, the width (W) and depth (GH) of the groove 20 formed on the surface of the sphere 10 and the height (H) of the projection 21 is applied to the groove ( 20) or the protrusions 21 may be formed.

The above description is merely illustrative of the technical spirit of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the claims below, and all technical ideas within the scope of the claims should be construed as being included in the scope of the present invention.

As described above, according to the present invention, since the grooves in the form of a mesh are formed on the surface of the sphere, the air distance is improved because the air resistance is similar to or smaller than that of the dimple golf ball.

In addition, since the area ratio of the groove to the golf ball surface area is considerably reduced, the occurrence of errors due to the groove bending during putting is reduced, so that accurate putting is possible.

Claims (10)

Grooves in the form of a net are formed on the surface of the sphere, The area of the groove is 14 to 69% of the surface area of the golf ball, The groove has a width of 4 mm or less, and the groove has a depth of 0.1 to 0.4 mm. The method of claim 1, The mesh-shaped grooves are interconnected or golf ball, characterized in that broken in the middle. Grooves in the form of a net are formed on the surface of the sphere, The area of the groove is 14 to 69% of the surface area of the golf ball, The width of the grooves is 1 to 5 mm, the depth of the grooves is 0.1 to 0.5 mm, The groove is a golf ball, characterized in that the projection is formed at least a height lower than the depth of the groove. The method of claim 3, The mesh grooves are interconnected or broken in the middle, The projections are golf balls, characterized in that they are interconnected or broken in the middle. The method according to any one of claims 1 to 4, The sphere surface is divided into spherical regular polyhedrons, a spherical regular polygon constituting the spherical regular polyhedron and a straight line connecting the center of the sphere, and a pinched angle of a straight line connecting the center of the sphere and the point of the sphere surface becomes a constant angle. The groove is formed along the circle connecting the dots of the golf ball. The method of claim 5, The spherical spherical polyhedron is a spherical cube or icosahedron, and the included angle is 45 to 80 ° golf ball. The method according to any one of claims 1 to 4, The sphere is divided into spherical tetrahedrons, a spherical regular polygon constituting the spherical regular polyhedron and a straight line connecting the center of the sphere, and the pinned angle of the straight line connecting the center of the sphere and the point of the sphere surface becomes a certain angle A golf ball, characterized in that the groove is formed along a circle connecting the points of the surface. The method of claim 7, wherein The spherical tetrahedron is a spherical octahedron or dodecahedron, and the included angle is 45 to 80 ° golf ball. The method according to any one of claims 1 to 4, Partitioning the sphere into a spherical polyhedron, the golf ball, characterized in that the groove is formed along the edge of the spherical polyhedron. The method of claim 9, The spherical polyhedron is a spherical icosahedron or a spherical icosahedron consisting of eight spherical pentagons and twelve spherical regular hexagons.

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