Golf ball

Abstract

A golf ball is provided having a dimpled surface, the configuration of the dimples comprising a dimple-free equatorial line on the ball dividing the ball into two hemispheres, with each hemisphere having substantially identical dimple patterns. The dimple pattern of each hemisphere comprises a first plurality of dimples extending in at least two spaced clockwise arcs between the pole and the equator of each hemisphere, a second plurality of dimples extending in at least two spaced counterclockwise arcs between the pole and the equator of each hemisphere, and a third plurality of dimples substantially filling the surface area between the first and second plurality of dimples.

Description

This invention relates generally to golf balls and more particularly to the arrangement of dimples on a golf ball and the method of arranging such dimples.

Dimples are used on golf balls as a standard means for controlling and improving the flight of the golf ball. One of the basic criteria for the use of dimples is to attempt to cover the maximum surface of the ball with dimples without incurring any detrimental effects which would influence the aerodynamic symmetry of the ball. Such aerodynamic symmetry is necessary in order to satisfy the requirements of the United States Golf Association (U.S.G.A.). Aerodynamic symmetry means that the ball must fly substantially the same with little variation no matter how it is placed on the tee or on the ground.

In British Patent Provisional Specification Serial No. 377,354, filed May 22, 1931, in the name of John Vernon Pugh, there is disclosed various triangular configurations which may be used to establish dimple patterns that are geometrical and which would also be aerodynamically symmetrical. Pugh uses a number of geometrical patterns wherein he inscribes a regular polyhedron of various types in order to provide such symmetry. The details of plotting and locating the dimples is described in the above-mentioned provisional specification.

The problem arises with the Pugh icosahedral golf ball in that there is no equatorial line on the ball which does not pass through some of the dimples. Since golf balls are molded and manufactured by two hemispherical half molds normally having straight edges, the ball as it comes from the mold has a flash line about the equatorial line created by the two hemispheres of the mold. Even if the ball could be molded with dimples on the flash line, the ball could not be properly cleaned and finished in any efficient manner since the flash could not be cleaned from the bottom of the dimple without individual treatment of each dimple.

Many proposals have been made and, in fact, many balls have been produced using modifications of the Pugh polyhedron concept, which leave an equatorial dimple-free line and still substantially maintain aerodynamic symmetry.

Other various proposals have been made and balls have been conformed which use differing means for locating the dimples on a golf ball. One such means is the use of a plurality of great circles about the ball, which great circles form triangles which include the dimples to be used on the golf ball. Again, these balls provide for an equatorial line free of dimples so that they may be molded.

There is a constant striving for dimple configurations which provide the necessary aerodynamic symmetry and which still allow for the maximum surface coverage on the golf ball.

Accordingly, it is an object of the present invention to provide a golf ball having dimples on the surface which assume a unique symmetry about the surface of the ball so that the ball will fly equally well regardless of its position on the tee.

It is also an object of this invention to provide a method for locating dimples on the surface of a ball so as to achieve aerodynamic symmetry.

Yet another object of the invention is to use a surface pattern for locating dimples on a golf ball which includes opposed arcs extending clockwise and counterclockwise between the pole and equator of the ball.

These and other objects of the invention will become obvious from the following description taken together with the drawings.

BRIEF SUMMARY OF THE INVENTION

A golf ball is provided having a dimpled surface, the configuration of the dimples comprising a dimple-free equatorial line on the ball dividing the ball into two hemispheres, with each hemisphere having substantially identical dimple patterns. The dimple pattern of each hemisphere comprises a first plurality of dimples extending in at least two spaced clockwise arcs between the pole and the equator of each hemisphere, a second plurality of dimples extending in at least two spaced counterclockwise arcs between the pole and the equator of each hemisphere, and a third plurality of dimples substantially filling the surface area between said first and second pluralities of dimples.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a view of a golf ball along an offset line from the equator line of the ball indicating the pole position;

FIG. 2 is a showing of the ball of FIG. 1 with the arcuate clockwise and counterclockwise lines drawn on the surface thereof;

FIG. 3 is a polar view of the ball of FIG. 2;

FIG. 4 is a polar view of the ball of FIG. 3 showing the location of dimples at the crossing points of the arcuate lines;

FIG. 5 is a polar view of the ball of FIG. 4 having additional dimples added along the arcuate lines;

FIG. 6 is a polar view of the ball of FIG. 5 modified by using different dimple sizes to avoid intersecting dimples;

FIG. 7 is a polar view of the ball of FIG. 6 with further dimples of different sizes being placed in the area between the dimples forming the arcuate lines;

FIG. 8 is an offset view of FIG. 7;

FIG. 9 is a view taken along an offset line from the equator line of the ball showing the finished ball without the arcuate lines thereon;

FIGS. 10-18 disclose some alternate arcuate configurations for providing further embodiments of the golf ball as disclosed in FIG. 9; and

FIG. 19 is a schematic showing of the measurement of dimple depth and diameter.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The drawings basically show a dimpled ball and a method for providing the dimple configuration of the present invention on the surface of a golf ball. It is to be stressed that the primary consideration in the basic concept of dimple configuration and all of the embodiments resulting therefrom is directed to the aspect of dimple symmetry so that the ball will have the necessary aerodynamic symmetry in flight regardless of its position on the tee or ground. FIGS. 1-9 disclose one embodiment of the present invention.

Referring to FIG. 1, there is shown a basic golf ball 11 having a surface which has no dimples thereon. In approaching the dimple configuration, one begins with an equatorial line E--E which in all cases must be dimple-free. This equatorial line obviously creates a pole P at the top and the bottom of the ball.

The basic concept of the present invention is to use sets of arcuate lines extending between the pole and the equator on each hemisphere of the ball. In order to obtain the symmetry desired, both hemispheres have dimple configurations which are substantially identical. FIGS. 1-9 show the development of one specific dimple configuration, resulting in one embodiment of the present invention. In this particular configuration, four sets of opposing clockwise and counterclockwise arcs are used to establish the basic dimple pattern.

As shown in FIG. 2, four arcs 13, 15, 17, and 19 originate at pole P and extend clockwise about the surface of the hemisphere and terminate at equator E--E. Four counterclockwise arcs 21, 23, 25, and 27 extend in like manner and equivalent arcuate configuration counterclockwise about the hemisphere of the ball from pole P to equator E--E. FIG. 3 shows a polar view of the arcs shown in FIG. 2.

In order to obtain symmetry, the present invention provides that dimples be placed along the lines of the arcs extending between pole P and equator E--E.

While various approaches could be taken to commence with the arrangement of these dimples, it is preferable that the dimples be originally located at each point wherein the clockwise and counterclockwise arcs intersect. This is specifically shown in FIG. 4, wherein dimples 31, all having the same diameter, have been placed so that their centers are substantially over the intersecting points of the arcs.

Referring to FIG. 5, additional dimples are added to the lines so that they substantially fill the arcs with dimples between pole P and equator E--E. As can be seen from FIG. 5, use of dimples of the same size will result in overlapping dimples such as indicated at 33. Although overlapping dimples may be used, it is preferable to cover the maximum amount of the surface of the ball while eliminating most or all such overlaps.

Turning to FIG. 6, it can be seen that one solution for eliminating the overlaps while still striving towards the coverage of the surface is to use dimples having different sizes. In this particular embodiment three different size dimples are used. The largest dimples 31 are of the diameter with which the method began, with the smaller dimples 35 and yet smaller dimples 37 being also used. FIG. 6 discloses the use of such dimples along the arcs so as to eliminate overlapping of any of the dimples.

It is noted that each of the clockwise arcs may include the identical pattern of dimples, including number, size, and location. Likewise, each of the counterclockwise arcs may include the identical pattern of dimples, including number, size, and location. This provides the symmetry which is discussed above.

The same criterion of maximum dimple coverage is used to complete the ball. FIG. 7 illustrates the use of dimples of three different sizes within the areas between the dimples which lie along the arcuate lines.

FIG. 8 is a view taken along an offset line from the equator showing the same dimple arrangement as FIG. 7.

FIG. 9 is a showing of the ball of FIG. 8 without any arcuate lines.

In the particular embodiment shown in FIGS. 2-9, three different size dimples are used. The dimples have the following diameters D and depths d:

______________________________________D1 = 0.165 Inch d1 = 0.0113 InchD2 = 0.140 Inch d2 = 0.0099 InchD3 = 0.110 Inch d3 = 0.0076 Inch______________________________________

FIG. 19 illustrates the standard measurement technique for dimple diameter and depth.

As will be evident from viewing the drawings, the adjustment of the dimples not only relates to using dimples of different diameters, but also to small adjustments of the location of the center of the dimples.

It should be noted that if a particular configuration of dimples is not within acceptable standards relative to aerodynamic symmetry, it is common practice to make minor modifications in dimple location and dimple depth without departing from the basic dimple pattern.

The ball of the embodiment shown in FIG. 9 is based on the four sets of opposed clockwise and counterclockwise arcs, with each arc being substantially helical and extending 360.degree. about the hemisphere between the pole and the equator. There are a total of 410 dimples, with 138 dimples having a diameter D1, 160 dimples having a diameter D2, and 112 dimples having a diameter D3. Each arc includes a common polar dimple D1, eight additional dimples having a diameter D1, nine dimples having a diameter D2, and two dimples having a diameter D3. As can be seen, each of the arcs share one dimple at the point of intersection of any two arcs. The hemispherical coordinates and the diameter of each dimple are indicated in the following chart:

__________________________________________________________________________DIMPLE LATITUDE LONGITUDE DIMPLENUMBER Degrees Minutes Seconds Degrees Minutes Second DIAMETER__________________________________________________________________________ 1 0 0 0 0 0 0 0.165 2 11 53 30 0 0 0 0.110 3 11 53 30 45 0 0 0.140 4 11 53 30 90 0 0 0.110 5 11 53 30 135 0 0 0.140 6 11 53 30 180 0 0 0.110 7 11 53 30 225 0 0 0.140 8 11 53 30 270 0 0 0.110 9 11 53 30 315 0 0 0.14010 18 32 0 19 6 45 0.11011 18 32 0 70 53 15 0.11012 18 32 0 109 6 45 0.11013 18 32 0 160 53 15 0.11014 18 32 0 199 6 45 0.11015 18 32 0 250 53 15 0.11016 18 32 0 289 6 45 0.11017 18 32 0 340 53 15 0.11018 22 24 0 45 0 0 0.16519 22 24 0 135 0 0 0.16520 22 24 0 225 0 0 0.16521 22 24 0 315 0 0 0.16522 23 27 45 0 0 0 0.11023 23 27 45 90 0 0 0.11024 23 27 45 180 0 0 0.11025 23 27 45 270 0 0 0.11026 28 45 15 25 39 0 0.14027 28 45 15 64 21 0 0.14028 28 45 15 115 39 0 0.14029 28 45 15 154 21 0 0.14030 28 45 15 205 39 0 0.14031 28 45 15 244 21 0 0.14032 28 45 15 295 39 0 0.14033 28 45 15 334 21 0 0.14034 30 53 45 8 17 0 0.11035 30 53 45 81 43 0 0.11036 30 53 45 98 17 0 0.11037 30 53 45 171 43 0 0.11038 30 53 45 188 17 0 0.11039 30 53 45 261 43 0 0.11040 30 53 45 278 17 0 0.11041 30 53 45 351 43 0 0.11042 33 55 45 45 0 0 0.16543 33 55 45 135 0 0 0.16544 33 55 45 225 0 0 0.16545 33 55 45 315 0 0 0.16546 37 40 15 0 0 0 0.11047 37 40 15 90 0 0 0.11048 37 40 15 180 0 0 0.11049 37 40 15 270 0 0 0.11050 38 13 15 28 43 0 0.14051 38 13 15 61 17 0 0.14052 38 13 15 118 43 0 0.14053 38 13 15 151 17 0 0.14054 38 13 15 208 43 0 0.14055 38 13 15 241 17 0 0.14056 38 13 15 298 43 0 0.14057 38 13 15 331 17 0 0.14058 41 7 30 13 57 0 0.14059 41 7 30 76 3 0 0.14060 41 7 30 103 57 0 0.14061 41 7 30 166 3 0 0.14062 41 7 30 193 57 0 0.14063 41 7 30 256 3 0 0.14064 41 7 30 283 57 0 0.14065 41 7 30 346 3 0 0.14066 44 31 0 39 0 15 0.11067 44 31 0 50 59 45 0.11068 44 31 0 129 0 15 0.11069 44 31 0 140 59 45 0.11070 44 31 0 219 0 15 0.11071 44 31 0 230 59 45 0.11072 44 31 0 309 0 15 0.11073 44 31 0 320 59 45 0.11074 47 47 15 0 0 0 0.14075 47 47 15 90 0 0 0.14076 47 47 15 180 0 0 0.14077 47 47 15 270 0 0 0.14078 49 27 0 21 28 45 0.14079 49 27 0 68 31 15 0.14080 49 27 0 111 28 45 0.14081 49 27 0 158 31 15 0.14082 49 27 0 201 28 45 0.14083 49 27 0 248 31 15 0.14084 49 27 0 291 28 45 0.14085 49 27 0 338 31 15 0.14086 52 21 45 33 13 15 0.14087 52 21 45 56 46 45 0.14088 52 21 45 123 13 15 0.14089 52 21 45 146 46 45 0.14090 52 21 45 213 13 15 0.14091 52 21 45 236 46 45 0.14092 52 21 45 303 13 15 0.14093 52 21 45 326 46 45 0.14094 53 51 30 10 14 15 0.14095 53 51 30 79 45 45 0.14096 53 51 30 100 14 15 0.14097 53 51 30 169 45 45 0.14098 53 51 30 190 14 15 0.14099 53 51 30 259 45 45 0.140100 53 51 30 280 14 15 0.140101 53 51 30 349 45 45 0.140102 56 28 15 45 0 0 0.165103 56 28 15 135 0 0 0.165104 56 28 15 225 0 0 0.165105 56 28 15 315 0 0 0.165106 58 51 0 0 0 0 0.140107 58 51 0 90 0 0 0.140108 58 51 0 180 0 0 0.140109 58 51 0 270 0 0 0.140110 61 8 30 24 2 0 0.165111 61 8 30 65 58 0 0.165112 61 8 30 114 2 0 0.165113 61 8 30 155 58 0 0.165114 61 8 30 204 2 0 0.165115 61 8 30 245 58 0 0.165116 61 8 30 294 2 0 0.165117 61 8 30 335 58 0 0.165118 64 13 0 11 20 30 0.165119 64 13 0 78 39 30 0.165120 64 13 0 101 20 30 0.165121 64 13 0 168 39 30 0.165122 64 13 0 191 20 30 0.165123 64 13 0 258 39 30 0.165124 64 13 0 281 20 30 0.165125 64 13 0 348 39 30 0.165126 65 4 15 34 34 15 0.110127 65 4 15 55 25 45 0.110128 65 4 15 124 34 15 0.110129 65 4 15 145 25 45 0.110130 65 4 15 214 34 15 0.110131 65 4 15 235 25 45 0.110132 65 4 15 304 34 15 0.110133 65 4 15 325 25 45 0.110134 67 50 15 45 0 0 0.165135 67 50 15 135 0 0 0.165136 67 50 15 225 0 0 0.165137 67 50 15 315 0 0 0.165138 69 25 30 0 0 0 0.140139 69 25 30 90 0 0 0.140140 69 25 30 180 0 0 0.140141 69 25 30 270 0 0 0.140142 72 42 30 21 18 0 0.165143 72 42 30 68 42 0 0.165144 72 42 30 111 18 0 0.165145 72 42 30 158 42 0 0.165146 72 42 30 201 18 0 0.165147 72 42 30 248 42 0 0.165148 72 42 30 291 18 0 0.165149 72 42 30 338 42 0 0.165150 74 42 0 33 5 0 0.165151 74 42 0 56 55 0 0.165152 74 42 0 123 5 0 0.165153 74 42 0 146 55 0 0.165154 74 42 0 213 5 0 0.165155 74 42 0 236 55 0 0.165156 74 42 0 303 5 0 0.165157 74 42 0 326 55 0 0.165158 75 34 0 9 26 30 0.165159 75 34 0 80 33 30 0.165160 75 34 0 99 26 30 0.165161 75 34 0 170 33 30 0.165162 75 34 0 189 26 30 0.165163 75 34 0 260 33 30 0.165164 75 34 0 279 26 30 0.165165 75 34 0 350 33 30 0.165166 79 8 15 45 0 0 0.165167 79 8 15 135 0 0 0.165168 79 8 15 225 0 0 0.165169 79 8 15 315 0 0 0.165170 79 18 0 0 0 0 0.110171 79 18 0 90 0 0 0.110172 79 18 0 180 0 0 0.110173 79 18 0 270 0 0 0.110174 83 47 15 24 36 45 0.165175 83 47 15 65 23 15 0.165176 83 47 15 114 36 45 0.165177 83 47 15 155 23 15 0.165178 83 47 15 204 36 45 0.165179 83 47 15 245 23 15 0.165180 83 47 15 294 36 45 0.165181 83 47 15 335 23 15 0.165182 84 46 45 35 54 15 0.140183 84 46 45 54 5 45 0.140184 84 46 45 125 54 15 0.140185 84 46 45 144 5 45 0.140186 84 46 45 215 54 15 0.140187 84 46 45 234 5 45 0.140188 84 46 45 305 54 15 0.140189 84 46 45 324 5 45 0.140190 85 0 15 14 6 30 0.140191 85 0 15 75 53 30 0.140192 85 0 15 104 6 30 0.140193 85 0 15 165 53 30 0.140194 85 0 15 194 6 30 0.140195 85 0 15 255 53 30 0.140196 85 0 15 284 6 30 0.140197 85 0 15 345 53 30 0.140198 85 39 15 4 54 15 0.110199 85 39 15 85 5 45 0.110200 85 39 15 94 54 15 0.110201 85 39 15 175 5 45 0.110202 85 39 15 184 54 15 0.110203 85 39 15 265 5 45 0.110204 85 39 15 274 54 15 0.110205 85 39 15 355 5 45 0.110__________________________________________________________________________

In order to further enhance the aerodynamic symmetry of the golf ball, the opposed hemispheres may be rotated relative to each other about an axis extending through the poles of the hemispheres. In the embodiment illustrated in FIG. 9, these hemispheres have been rotated 45.degree.. The desired optimum rotation will depend primarily upon how many sets of arcs are used.

The ball described in FIGS. 1-9 has been tested and meets U.S.G.A. requirements relative to aerodynamic symmetry.

In order to obtain the proper results, at least two sets of opposed clockwise and counterclockwise arcs must be used. The number of sets used may be varied, however, and still obtain the same desired aerodynamically symmetrical results. Additionally, the arcs could extend less than or more than 360.degree. and still provide practical data lines and points for the proper placement of dimples. It should be further noted that the diameter of the dimples is not limited to three different diameters, but may be varied in a manner which is considered to be desirable. Obviously, different configurations using different diameter dimples may be used in order to provide a greater surface coverage; but use of the same diameter dimples will result in a useable ball.

The embodiments shown in FIGS. 10-18 disclose different arc configurations. For clarity purposes, the dimples are not shown on these configurations; but the placement of such dimples would be obvious when following the method previously described relative to the ball of FIGS. 1-9. It is also to be understood that the disclosed configurations are not to be considered as limiting the invention, but merely as examples of various embodiments which may be used under the invention.

FIG. 10 discloses a configuration using six sets of clockwise and counterclockwise arcs which extend 360.degree. between the pole and the equator.

FIG. 11 discloses a configuration using seven sets of opposed clockwise and counterclockwise arcs, with each arc extending 270.degree. between the pole and the equator.

FIG. 12 discloses a configuration using five sets of opposed clockwise and counterclockwise arcs which extend 270.degree. between the pole and the equator.

FIG. 13 discloses a configuration using five sets of opposed clockwise and counterclockwise arcs which extend 360.degree. between the pole and the equator.

FIG. 14 discloses a configuration using four sets of opposed clockwise and counterclockwise arcs extending 450.degree. between the pole and the equator.

FIG. 15 discloses a configuration having eight sets of opposed clockwise and counterclockwise arcs extending 270.degree. between the pole and the equator.

FIG. 16 discloses a configuration having six sets of opposed clockwise and counterclockwise arcs extending 270.degree. between the pole and the equator.

FIG. 17 discloses a configuration having three sets of opposed clockwise and counterclockwise arcs extending 450.degree. between the pole and the equator.

FIG. 18 discloses a configuration having three sets of opposed clockwise and counterclockwise arcs extending 540.degree. between the pole and the equator.

It is to be understood the above description and drawings are illustrative only since modifications could be made without departing from the invention, the scope of which is to be limited only by the following claims.

Claims

1. A golf ball having a dimpled surface, the configuration of said dimpled surface comprising

a dimple-free equatorial line on said ball dividing said ball into two hemispheres with each hemisphere having a pole and substantially identical dimple patterns, each hemispherical dimple pattern comprising

at least two spaced imaginary arcs extending clockwise between said pole and said equator on said surface;

at least two spaced imaginary arcs extending counterclockwise between said pole and said equator on said surface;

a plurality of dimples extending along each of said arcs between said pole and said equator; and

a second plurality of dimples substantially filling the surface area enclosed within said arcs.

2. The golf ball of claim 1 wherein each of said clockwise arcs has the same number of dimples and each of said counterclockwise arcs have the same number of dimples.

3. The golf ball of claim 1 wherein each of said arcs terminates at one end within a common polar dimple.

4. The golf ball of claim 1 wherein a dimple is located substantially at each point on the surface of said hemisphere where said clockwise arcs cross said counterclockwise arcs.

5. The golf ball of claim 1 wherein said dimples are of at least two different diameters.

6. The golf ball of claim 5 wherein each of said clockwise arcs has the same dimple configuration and each of said counterclockwise arcs has the same dimple configuration.

7. The golf ball of claim 1 wherein said arcs are helices.

8. The golf ball of claim 1 wherein each of said arcs on said hemisphere extends substantially 360.degree. about the hemisphere between the pole and the equator.

9. The golf ball of claim 1 wherein each of said arcs on said hemisphere extends less than 360.degree. about the hemisphere between the pole and the equator.

10. The golf ball of claim 1 wherein each of said arcs on said hemisphere extends more than 360.degree. about the hemisphere between the pole and the equator.

11. The golf ball of claim 1 wherein none of said dimples overlap each other.

12. The golf ball of claim 1 wherein said two hemispheres are rotated with respect to each other a predetermined degree about an axis through the said poles.

13. A method of locating dimples on the surface of a golf ball comprising

designating opposite pole locations and an equator between said poles to create two equal hemispheres;

establishing at least two arcs extending clockwise between said pole and said equator on the surface of each of said hemispheres;

establishing at least two arcs extending counterclockwise between said pole and said equator on the surface of each of said hemispheres;

locating a plurality of dimples along said arcs; and substantially filling the area within said arcs with dimples, the total number of said dimples being the same for both hemispheres.

14. The method of claim 13 wherein each of said arcs terminates in a common polar dimple.

15. The method of claim 13 further comprising locating a dimple substantially at each point where said clockwise and counterclockwise arcs intersect.

16. The method of claim 13 wherein said arcs are helices.

17. The method of claim 13 wherein said arcs on the surface of said hemispheres extend substantially 360.degree. between said poles and said equator.

18. The method of claim 13 wherein said arcs on the surface of said hemispheres extend less than 360.degree. between said poles and said equator.

19. The method of claim 13 wherein said arcs on the surface of said hemispheres extend more than 360.degree. between said pole and said equator.

20. The method of claim 13 wherein said dimples are of at least two different diameters.

21. The method of claim 13 wherein none of said dimples overlap each other.

22. A golf ball having a dimpled surface with a dimple-free equatorial line dividing the ball into two hemispheres, each hemisphere having a pole, each of said hemispherical dimpled surfaces comprising

a first plurality of dimples extending in at least two spaced clockwise arcs between said pole and said equator;

a second plurality of dimples extending in at least two spaced counterclockwise arcs between said pole and said equator; and

a third plurality of dimples substantially filling the surface area between said first and second plurality of dimples.

23. The golf ball of claim 22 wherein a dimple is located substantially at each point on said surface of said hemisphere where said clockwise arcs cross said counterclockwise arcs.

24. The golf ball of claim 22 wherein said clockwise and counterclockwise arcs are helical.

25. The golf ball of claim 22 wherein said clockwise arcs and said counterclockwise arcs in each of said hemispheres extend substantially 360.degree. between said pole and said equator.

26. The golf ball of claim 22 wherein said first, second, and third pluralities of dimples are comprised of dimples which are of at least two different diameters.

27. The golf ball of claim 22 wherein each of said pluralities of dimples extending in a clockwise arc has the same number of dimples and each of said pluralities of dimples extending in a counterclockwise arc has the same number of dimples.

28. The golf ball of claim 22 wherein each of said clockwise and counterclockwise arcs terminate at one end in a common polar dimple.

29. The golf ball of claim 22 wherein said arcs are helices.

30. The golf ball of claim 22 wherein said clockwise and counterclockwise arcs extend more than 360.degree. between said pole and said equator.

31. The golf ball of claim 22 wherein said clockwise and counterclockwise arcs extend less than 360.degree. between said pole and said equator.

32. A golf ball having a dimpled surface with a dimple-free equatorial line dividing the ball into two hemispheres, each hemisphere having a pole, each of said hemispherical surfaces comprising

a first plurality of dimples extending in four spaced clockwise arcs between said pole and said equator, said plurality of dimples comprising dimples having different diameters D1, D2, and D3;

a second plurality of dimples extending in four spaced counterclockwise arcs between said pole and said equator, said plurality of dimples having different diameters D1, D2, and D3;

a third plurality of dimples substantially filling the surface area between said first and second plurality of dimples;

said third plurality of dimples having different diameters D1, D2, and D3.

33. The golf ball of claim 32 wherein said dimpled surface contains 410 dimples comprising 138 dimples having a diameter D1, 16 dimples having a diameter D2, and 112 Dimples having a diameter D3.

34. The golf ball of claim 33 wherein the diameter D and the depth d of said dimples are

______________________________________ Diameter DepthDimple (Inches) (Inches)______________________________________D1 0.165 0.0113D2 0.140 0.0099D3 0.110 0.0076______________________________________

35. The golf ball of claim 34 wherein each of said arcs include a common pole dimple having a diameter D1;

eight additional dimples D1;

nine dimples having a diameter D2; and

two dimples having a diameter D3, each of said arcs having a common dimple at a crossing point of any two arcs.