AU2002213383A1

AU2002213383A1 - Progressive depth oblong dimples

Info

Publication number: AU2002213383A1
Application number: AU2002213383A
Authority: AU
Inventors: Daniel Murphy
Original assignee: Top Flite Golf Co
Current assignee: Topgolf Callaway Brands Corp
Priority date: 2000-10-19
Filing date: 2001-10-18
Publication date: 2002-04-29
Also published as: GB2385798A; WO2002032512A9; CA2426608A1; GB0311362D0; US6475105B1; GB2385798B; WO2002032512A1

Description

PROGRESSIVE DEPTH OBLONG DIMPLES

This application is a continuation-in-part of U.S. application serial number 09/285,698 filed April 4, 1999, which is a continuation-in-part of U.S. application serial number 08/869,981 filed June 5, 1997, now patent No. 5,890,975. This invention relates generally to the dimple configuration on the surface of a golf ball and more particularly to an elongated dimple configuration and the method of obtaining that configuration.

BACKGROUND OF THE INVENTION

Golf balls are now being produced having various dimple patterns, dimple sizes, and geometric dimple patterns. Generally speaking, all of these dimples are configured so as to have a substantially constant geometric surface. Whether circular or multi-sided, the dimples are designed so that the geometrical configuration of each dimple is substantially the same regardless of its size. In this type of dimple arrangement, the dimples are normally configured in some pattern such as an octahedron, dodecahedron, or the like, or are configured so as to provide sections within the hemisphere, whether those sections number four, or six, or whatever desired configuration. Normally, the dimples are arranged in a desired pattern within each section and then this pattern is repeated for each section. The standard procedure is that each hemisphere has the same number of dimples and in substantially the same pattern and the hemispheres may be rotated with respect to each other depending upon the position of the mold halves. U.S. Patent 5,356,150 issued October 18, 1994 and assigned to the assignee of the present invention discloses a golf ball having a plurality of dimples formed on the spherical surface of the golf ball, with the surface defining opposite and depths. Further, a pattern may include dimples having different partial drag lengths.

SUMMARY OF THE INVENTION

According to a primary object of the invention, elongated dimples may be formed by drilling into a spherical surface to a first depth with a drill bit having a first radius and by displacing the drill bit and/or the spherical surface along a V- shaped path. This produces an oblong depression having a longitudinal axis and a length measured along the axis greater than a width measured perpendicular to the axis. In cross-section, the depression has a V-shaped configuration.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a perspective off-equator view showing a basic dimple pattern section which is repeated about the surface of the ball in each hemisphere;

Fig. 2 is a perspective off equator view showing a finished ball incorporating the pattern of Fig 1; Figs. 3 and 3 A show a plan view and a cross-sectional view of a basic circular dimple;

Figs. 4 and 4A show a plan and cross-sectional view of an elongated dimple formed by having a partial dimple drag;

Figs. 5 and 5A show a plan and cross-sectional view of an elongated dimple formed by having a full dimple drag;

Fig. 6 is a perspective off-equator view showing a modified basic elongated dimple pattern section which is repeated about the surface of the ball;

Figs. 7 and 7A show a plan and cross-sectional view of a further elongated dimple formed by having a partial dimple drag; Figs. 8 and 8A show a plan and cross-sectional view of a further elongated dimple formed by having a full dimple drag;

Fig. 9 is a perspective off-equator view showing a finished ball incorporating the pattern of Fig. 6; Fig.10 is an enlarged cross-sectional view comparing dimples of different depths;

Figs. 11-13 are plan views, respectively, showing different techniques for drilling elongated dimples into a spherical surface according to a further embodiment of the invention; Figs. 14 and 15 are plan and sectional views of a dimple formed with displacement relative to a cutting tool in a straight line.

Figs. 16 and 17 are plan and sectional views of a dimple formed with displacement relative to a cutting tool in a curved line;

Figs. 18 and 19 are plan and sectional views of a dimple formed with displacement relative to a cutting tool in two different straight directions;

Fig. 20 is a plan view of a further technique for drilling elongated dimples into a spherical surface according to another embodiment of the invention;

Figs. 21 and 22 are plan and sectional views, respectively, of a symmetrical dimple formed with displacement of a cutting tool in a V-shaped path with the same angles of entry and exit; and

Figs. 23 and 24 are plan and sectional views, respectively, of an asymmetrical dimple formed with displacement of a cutting tool in a V-shaped path with different angles of entry and exit.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Fig. 1 shows the basic pattern used to develop the dimple coverage in one example of the present invention. The ball is divided into two hemispheres 11 and

12 divided by a dimple free equator E-E. A basic pattern section is shown on hemisphere 11. The pattern shows two different dimples 2 and 3 which will be described in detail below.

Fig. 2 is an off-equator view of a finished ball where substantially all of the dimples are dimples 2 and 3 as described above. As can be seen, a ball is provided which has substantially no dimple overlap. By creating dimples 2 by partial dimple drag as described above, it is possible to increase the percent dimple coverage over the coverage obtained using circular dimples in combination with elongated dimples 3 formed by full dimple drag since the surface area between dimples is reduced.

This pattern of Fig. 1 is repeated five times about the surface of hemisphere 11 except that all repeating patterns share a common pole dimple.

This same pattern appears on hemisphere 12.

All of the elongated dimples 2 are substantially identical and all of the elongated dimples 3 are substantially identical. The specific configuration of these dimples is discussed below. Dimples X are formed by the five core pins in each hemisphere which support the core within the mold while the cover is being formed. Due to the position of the core pins and the manner of their creation, dimples X are elliptical.

The two polar dimples P are formed by vent pins during the formation of the cover and are substantially circular. Each key pattern includes 33 dimples plus the common pole dimple P which, when duplicated completely over the ball in the manner described above, results in a ball having a total of 332 dimples as shown in Fig. 2.

Figs. 3, 3A, 4, 4A, and 5, 5A illustrate the progression of dimple formation as used in the present invention. Fig. 3 is an illustration of a circular dimple as used on most golf ball surfaces at the present time. This dimple has a constant radius. Thus, the two axes Al are equal. Arrow 20 indicates the initial direction of the drill which is used to form the dimple in 3A. The drill (not shown) extends into the spherical ball outer periphery at point C until the desired depth Dl is reached. Fig. 4 illustrates dimple 2 of Fig. 1. Again the dimple is formed to the desired depth D2. Since the formation of this dimple starts with a circular dimple as in Fig. 3, the minor axis Al is the same as the radius of the circular dimple. Dimple drag as discussed above, is in the direction indicated by arrow 15. In the illustration of Fig. 4, 4A partial dimple drag results in major axis A2 which is greater than axis A 1.

Fig. 5 illustrates dimple 3 of Fig. 1 which has been formed using a full dimple drag. That is, the cutting drill is dragged until it leaves the curving surface of the ball. Again, since dimple 3 starts with a circular dimple, minor axis Al is the same as minor axis Al of Fig. 3. The full dimple drag produces an elongated dimple 3 having major axis A3 which is greater than axis A2 of elongated dimple 2.

Figs. 3 A, 4A and 5 A which are cross-sectional views taken along lines 3 A, 4A, and 5A of Figs. 3, 4, and 5 show the depth of the dimples of Figs. 3, 4, and 5. The maximum depths Dl, D2 and D3 occur vertically below point C where the major and minor axes meet. Although varying depths may be selected, in the example below, all depths are equal. The selected depth is one of the parameters which controls the height of the trajectory of the ball.

Example 1

One example of a specific ball, as shown in Fig. 2, is as follows. This ball has a total of 332 dimples with substantially all of the dimples having the configuration as shown in Figs. 4, 4A and 5, 5A. The outside diameter of the ball is substantially 1.68 inches.

Dimple Minor Axis Major Axis Number of Dimples Dimple Depth 2 0.074 in. 0.088 in. 220 0.0117 in. 3 0.074 in. 0.140 in. 100 0.0117 in.

As discussed above, there are ten (10) elliptical core dimples and two (2) circular polar vent dimples. This dimple pattern results in a ball having a surface dimple coverage of substantially 77%.

Fig. 6 is a perspective off -equator view of a modified basic elongated dimple pattern which comprises four different sizes of elongated dimples 4, 5, 6, and 7. Elongated dimples 4 and 5 are formed starting with a dimple depression having the same diameter. Elongated dimples 6 and 7 are formed starting with a dimple depression having a different diameter than the dimple depression used for elongated dimples 4 and 5. Using the basic illustrations of Figures 4 and 5 as applied to Figure 6, dimples 4 and 5 have a minor axis Al. Dimple 4 has a full dimple drag resulting in a major axis A3. Dimple 5 has a partial dimple drag resulting in a major axis A2. As shown in Figs 7, 7A, 8 and 8A, dimples 6 and 7 have a minor axis Al'. Dimple 6 has a full dimple drag resulting in major axis A3'. Dimple 7 has a partial dimple drag resulting in a major axis A2'<A3'. Thus dimples 4 and 5 have a minor axis Al and dimples 6 and 7 have a minor axis AT. Axis Al differs from axis AT since two different diameter dimple depressions are used. This forms a final pattern having four different size elongated dimples with substantially no dimple overlap wherein the sum of the major and minor axes differs in the four different elongated dimples. Again, the pattern of Figure 6 is repeated in each hemisphere 21 and 22 so as to provide the finished ball as shown in Figure 9.

Example 2

One example of a specific ball using the pattern of Figs 6 and 9 is as follows. This ball has a total of 332 dimples with substantially all of the dimples having an elongated configuration. This specific ball has an outside diameter of substantially 1.68 inches. Elongated dimples 4 and 6 are produced with a full dimple drag while dimples 5 and 7 are produced with a partial dimple drag. This ball provides a dimple coverage of substantially 75%.

Major Axis

Dimple Length Number of Dimples Diameter Depth

4 Full 0.1403 in. 40 0.1400 in. 0.0117 in.

5 Partial 0.0846 in. 60 0.1400 in. 0.0117 in.

6 Full 0.1403 in. 60 0.1480 in. 0.0117 in

7 Partial 0.0880 in. 160 0.1480 in. 0.0117 in

P&X Ellip fdτ 0.0740 in. 12 0.1480 in. 0.0117 in

The selected depth of the original dimple depression is directly related to the length of the longitudinal axis of the elongated dimple resulting from dimple drag. This relationship is illustrated in Fig.10 which shows an elongated view of the cross section of elongated dimples having different maximum depths. These dimples are produced with full dimple drag. Elongated dimple 23 has a maximum depth D8 which is less than the maximum depth of dimple D9 of dimple 24. This results in a difference ΔA in the total axis length of the two dimples.

Although the golf ball of the present invention could be produced by drilling each ball, such a procedure is not economically feasible. A procedure which has become standard in the industry is disclosed in U.S. Patent 3,831,423 to Brown et al, issued August 27, 1994. In this procedure, a hob is made of approximately the same dimensions as half of the finished golf ball and then a mold is formed from the hob.

Referring now to Figs. 11-13, alternate methods for drilling a hob 24 in accordance with further embodiments of the invention will now be described.

The hob has a hemispherical surface 26 which represents the outer surface of a golf ball. A cutting tool 28 is arranged adjacent the hob and includes a drill bit 30 having a first radius. In the embodiment of Fig. 11, the hob is fixed and the drill bit is displaced along a straight line represented by the arrows 32. When the drill bit strikes the hob surface, it cuts a dimple therein as it traverses the surface. Such a dimple 34 is shown in Fig. 14. It is elongated because of the curvature of the surface and includes a center C along a radius of the hob. The center is also equidistant from the opposite edge of the dimple. The dimple has equal major axes A" which are co-linear with the straight line of movement of the cutting tool 28. The depth D of the dimple (Fig. 15) is defined by the degree to which the cutting tool cuts into the hob along the radius thereof. The depth is adjustable by vertically displacing the cutting tool as shown by the arrows 36. Because the cutting tool moves along a straight line, the deepest portion of the dimple is also defined by a straight line LI extending between the portions of the hob surface where the drill bit enters and leaves the same as shown in Fig. 15.

In lieu of displacing the cutting tool relative to the fixed hob, the same results can be achieved by fixing the tool and displacing the hob in a straight line. Fig. 12 represents a further embodiment for cutting a hemispherical surface on a hob. In this embodiment, the cutting tool moves along a curved path represented by the arrows 38. Thus, during the period which the drill bit 30 engages the surface 26 of the hob 24, the bit enters the hob with a lateral downward movement and exits the hob with a lateral upward movement as shown in Fig. 12. The resulting elongated dimple 40 is shown in Figs. 16 and 17. It is elongated but blunted at the ends thereof in comparison with the dimple 34 of Figs. 14 and 15. This is because of the angle at which the drill bit enters and leaves the hob. Thus, as shown in Fig. 17, the deepest portion of the dimple defines a line L2 which is curved at its opposite ends. The dimple 40 also has equal major axes A'".

Fig. 13 shows an alternate embodiment for producing a dimple 40 configured as in Figs. 16 and 17. The cutting tool 28 is stationary and the hob 24 is pivotable through an arc with respect to the drill bit.

The description of Figs. 11-13 above is for a cutting tool or hob being displaced within a plane in a first direction to produce the dimples 34 or 40 of Figs. 14 and 16. It is also possible to displace the cutting tool or hob in a second plane during drilling to produce a dimple whose major axes are not co-linear. Such a dimple 42 is shown in Figs. 18 and 19 and has a kidney-shaped configuration. By way of example only, the dimple 42 has first and second semi-elliptical portions 42a and 42b. The portion 42a has a major axis A" and is formed in the same manner as the first half of the dimple 34 of Fig. 14. However, when the center of the drill bit reaches the center C of the dimple (which is along a radius of the hob), so that the radius of the hob and the axis of the cutting tool are aligned, the cutting tool is redirected for movement in a second direction or plane to form the portion 42b which also has a major axis A". Thus, the major axes intersect rather than being co-linear.

In Fig. 20 there is shown a further embodiment for cutting an elongated dimple into a hob 124. This embodiment is similar to that of Fig. 12 except that the cutting tool 128 moves along a V-shaped path 138 rather than a curved path. That is, the drill bit 130 descends into the hob at an angle α relative to a horizontal axis of the hemispherical surface 126 of the hob and exits the surface at an angle β. Preferably, the angles α and β are equal. The transition between entry and exit from the hob surface occurs at the center C of the resulting dimple 140 shown in Fig. 21 on opposite sides of equal axes A"". The center C thus has the maximum depth D as shown in Fig. 22. Moreover, because there is no lateral movement of the cutting tool without a vertical displacement of the tool (as shown by the arrow 136), the bottom of the dimple does not have a flattened portion as does the dimple 40 of Fig.16. Rather, the dimple has a corresponding V-shaped profile as shown in Fig. 22. The steeper the angles of entry and exit of the cutting tool into the hob, the less elongated the dimple is and the steeper the bottom surfaces L3 of the dimple are.

Although it is preferred that the angles of entry α and exit β of the cutting tool are equal, an oblong dimple 240 which is non-symmetric is defined where the angles differ. Figs. 23 and 24 show such a dimple where the exit angle β is greater than the entry angle α. In this instance the axis Al is greater than the axis A2 and the deepest portion, i.e. depth D, of the dimple is offset from the center thereof. The bottom surface L4 is longer than the bottom surface L5.

It will be appreciated by those skilled in the art that an infinite number of elongated dimple configurations are possible by using the drilling methods described above. Variable dimple depths within a single dimple are available by extending or retracting the cutting tool relative to the hob during the drilling step. Moreover, the direction of travel of the cutting tool relative to the hob can be reoriented through a number of planes during drilling.

While in accordance with the provisions of the patent statutes the preferred forms and embodiments have been illustrated and described, it will be apparent to those of ordinary skill in the art that various changes may be made without deviating from the inventive concepts set forth above.

Claims

WHAT IS CLAIMED IS:

1. A dimple for a golf ball, comprising an oblong depression having a longitudinal axis and a length measured along said axis being greater than a width measured perpendicular to said axis, said depression having a V- shaped configuration when viewed in a section taken through said longitudinal axis.

2. A dimple as defined in claim 1, wherein said dimple has a symmetrical configuration and a maximum depth located at a midpoint of said longitudinal axis.

3. A dimple as defined in claim 1, wherein said dimple has an asymmetrical configuration and a maximum depth along said longitudinal axis offset from a midpoint thereof.