Golf ball

Information

  • Patent Grant
  • 5766098
  • Patent Number
    5,766,098
  • Date Filed
    Wednesday, September 20, 1995
    29 years ago
  • Date Issued
    Tuesday, June 16, 1998
    26 years ago
Abstract
A two-piece golf ball of improved playing characteristics comprisinga core having a weight of substantially 34.4 grams anda cover having a weight of substantially 11.1 grams. The ball has a total weight of no more than 46.0 grams and a dimple pattern covering at least 70.0% of the surface of the ball.
Description

This invention relates to golf balls. In particular, it relates to a two-piece golf ball having playability characteristics which are improved relative to state-of-the-art balls.
According to United States Golf Association (U.S.G.A.) rules, a golf ball may not have a weight in excess of 1.620 ounces or a diameter smaller than 1.680 inches. The initial velocity of U.S.G.A. "regulation" balls may not exceed 250 feet per second with a maximum tolerance of 2%. Initial velocity is measured on a standard machine kept by the U.S.G.A. A projection on a wheel rotating at a defined speed hits the test ball, and the length of time it takes the ball to traverse a set distance after impact is measured. U.S.G.A. regulations also require that a ball not travel a distance greater than 280 yards when hit by the U.S.G.A. outdoor driving machine under specified conditions. In addition to this specification, there is a tolerance of plus 4% and a 2% tolerance for test error.
These specifications limit how far a golf ball will travel when hit in several ways. Increasing the weight of a golf ball tends to increase the distance it will travel and lower the trajectory. A ball having greater momentum is better able to overcome drag. Reducing the diameter of the ball also has the effect of increasing the distance it will travel when hit. This is believed to occur primarily because a smaller ball has a smaller projected area and, thus, a lower drag when travelling through the air. Increasing initial velocity increases the distance the ball will travel.
The foregoing generalizations hold when the effect of size, weight, or initial velocity is measured in isolation. Flight characteristics (influenced by dimple pattern and ball rotation properties), club head speed, radius of gyration, and diverse other factors also influence the distance a ball will travel.
In the manufacture of top-grade golf balls for use by professional golfers and amateur golf enthusiasts, the distance a ball will travel when hit (hereinafter referred to as "distance") is an important design criterion. Since the U.S.G.A. rules were established, golf ball manufacturers have designed top-grade U.S.G.A. regulation balls to be as close to the maximum weight, minimum diameter, and maximum initial velocity as golf ball technology will permit. The distance a ball will travel when hit has, however, been improved by changes in raw materials and by alternations in dimple configuration.
Golf balls not conforming to U.S.G.A. specifications in various respects have been made in the United States. Prior to the effective date of the U.S.G.A. rules, balls of various weights, diameters, and resiliencies were common. So-called "rabbit balls," which claim to exceed the U.S.G.A. initial velocity limitations, have also been offered for sale. Recently, oversized, overweight golf balls have been on sale for use as golf teaching aids (see U.S. Pat. No. 4,201,384 to Barber).
Oversized golf balls are also disclosed in New Zealand Patent 192,618 dated Jan. 1, 1980, issued to a predecessor of the present assignee. This patent discloses an oversized golf ball having a diameter between 1.700 and 1.730 inches and an oversized core of resilient material so as to increase the coefficient of restitution. Additionally, the patent discloses that the ball should include a cover having a thickness less than the cover thickness of conventional balls. The patent has no disclosure as to dimple size or the percentage of surface coverage by the dimples.
Golf balls made by Spalding in 1915 were of a diameter ranging from 1.630 inches to 1.710 inches. While these balls had small shallow dimples, they covered less than 50% of the surface of the ball. Additionally, as the diameter of the ball increased, the weight of the ball also increased.
Golf balls known as the LYNX JUMBO were also produced and sold in October of 1979. This ball had a diameter of substantially 1.80 inches. The dimples on the LYNX JUMBO balls had 336 Atti-type dimples with each dimple having a diameter of 0.147 inch and a depth of 0.0148 inch. With this dimple arrangement, 56.02% of the surface area of the ball was covered by the dimples. This ball met with little or no commercial success.
Top-grade golf balls sold in the United States may be classified as one of two types: two-piece or three-piece. The two-piece ball, exemplified by the balls sold by Spalding Corporation under the trademark TOP-FLITE, consists of a solid polymeric core and a separately formed cover. The so-called three-piece balls, exemplified by the balls sold under the trademark TITLEIST by the Acushnet Company, consist of a liquid (e.g., TITLEIST TOUR 384) or solid (e.g., TITLEIST DT) center, elastomeric thread windings about the center, and a cover. Although the nature of the cover can, in certain instances, make a significant contribution to the overall coefficient of restitution and initial velocity of a ball (see, for example, U. S. Pat. No. 3,819,768 to Molitor), the initial velocity of two-piece and three-piece balls is determined mainly by the coefficient of restitution of the core. The coefficient of restitution of the core of wound balls can be controlled within limits by regulating the winding tension and the thread and center composition. With respect to two-piece balls, the coefficient of restitution of the core is a function of the properties of the elastomer composition from which it is made. Solid cores today are typically molded using polybutadiene elastomers mixed with acrylate or methacrylate metal salts. High-density fillers such as zinc oxide are included in the core material in order to achieve the maximum U.S.G.A. weight limit.
Improvements in cover and core material formulations and changes in dimple patterns have more or less continually improved golf ball distance for the last 20 years. Top-grade golf balls, however, must meet several other important design criteria. To successfully compete in today's golf ball market, a golf ball should be resistant to cutting and must be finished well; it should hold a line in putting and should have good click and feel. With a well-designed ball, experienced players can better execute shots involving draw, fade, or abrupt stops, as the situation dictates.
SUMMARY OF THE INVENTION
The golf ball of the present invention provides an improvement over previously proposed oversized golf balls. The present ball, even though of a larger diameter of at least 1.70 inches, preferably uses substantially the same size core as a standard golf ball, with the difference in size being provided by additional thickness in the cover of the ball. The enlarged ball includes dimples which cover at least 70% of the surface of the ball, which enhances the flight characteristics of the ball. It has been found that large diameter shallow dimples further enhance the flight characteristics of the golf ball as opposed to the use of a large number of small diameter dimples.
In addition to allowing the use of larger diameter dimples, the larger diameter ball provides a moment which is greater than the conventional ball. This greater moment reveals itself by having a lower backspin rate after impact than the conventional ball. Such a lower backspin rate contributes to straighter shots, greater efficiency in flight, and a lesser degree of energy loss on impact with the ground. On impact with the ground, all balls reverse their spin from backspin to over-spin; hence, having lower backspin on impact, less energy is absorbed in this reversal than with conventional balls. This is especially true with woods because of the lower trajectory resulting from a lower backspin. As a result, the ball strikes the ground at a more acute angle, adding increased roll or distance.
The present ball provides additional control due to the enlarged size of the ball and dimple coverage while still maintaining maximum performance standards as compared to a standard ball.
The advantages of the present invention will be more clearly understood from the following description taken together with the drawings.





BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrates a partially broken-away view of an embodiment of the improved golf ball of the present invention;
FIG. 2 illustrates dimple diameter and depth measurements;
FIG. 3 discloses a golf ball of the dimensions as shown in FIG. 1 with a particular dimple configuration;
FIG. 4 is a schematic illustration showing dimple size and location of the repetitive sections of the golf ball of FIG. 3;
FIG. 5 is a modified dimple pattern of the present invention; and
FIG. 6 is a further modified dimple pattern of the present invention.





DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The following description relates to several particular embodiments of the golf ball of the present invention, but the concept of the present invention is not to be limited to such embodiments. It should be noted that all of the specific dimensions set forth have a manufacturing tolerance of .+-.0.05%. Additionally, all of the balls have a weight no greater than 1.62 ounces.
The diameter of the ball is substantially between 1.70 and 1.80 inches. When dimples having different diameters and depths are used, weighted average dimple diameter is used in relation to the following parameters. Obviously, when all the dimples used are of the same diameter and depth, the weighted average diameter and depth is the same as each dimple diameter and depth. The weighted average diameter of the dimples covering the ball is substantially between 0.100 and 0.190 inch, preferably between 0.135 and 0.170 inch, with the preferred weighted average dimple diameter being between 0.139 and 0.149 inch. The weighted average depth of the dimples covering the ball is between 0.005 and 0.015 inch, preferably between 0.009 and 0.013 inch, with the preferred depth being between 0.010 and 0.011 inch.
Referring to FIG. 1, there is disclosed a ball having an oversized diameter D as compared to the diameter of a standard ball. The ball has a core of a diameter C and a cover of a thickness T. As opposed to previously proposed golf balls such as that disclosed in the above-mentioned New Zealand patent, the present invention does not use an over-size core in the oversized golf ball. In the particular ball used for illustrative purposes, the nominal diameter of the ball is 1.717.+-.0.010 inches, the diameter of the core is 1.545.+-.0.010 inches, and the cover thickness is 0.086.+-.0.010 inch.
The dimple pattern discussed above provides coverage of between 70% and 85% of the surface of the ball. It should be noted that if maximum possible coverage is desired, non-circular dimples can be used to fill in open surface areas which may remain after the basic dimple pattern is determined.
The core uses conventional ingredients, but is adjusted to produce a softer center. The total amount of filler, and, thus specific gravity, is less than the standard ball since the larger ball must weigh the same as the standard ball. The cover of the ball, while being substantially thicker, is made of the standard cover material used in most two-piece golf balls.
Referring to FIGS. 3 and 4, there is shown a ball having the enlarged dimensions of the present invention and having a dimple pattern including 422 dimples, which includes dimples of three different diameters and depths measured in accordance with FIG. 2. As indicated in FIG. 4, the largest dimple diameter is 0.169 inch with a dimple depth of 0.0123 inch, the intermediate dimple diameter is 0.157 inch with a dimple depth of 0.0123 inch, and the smallest dimple diameter is 0.145 inch with a dimple depth of 0.0101 inch. With the pattern shown, the resultant weighted average dimple diameter is 0.1478 inch and the weighted average dimple depth is 0.0104 inch. With this configuration and dimple size, 78.4% of the surface area of the ball is covered by dimples without any dimple overlap. The ball of FIG. 3 includes repeating patterns about each hemisphere, with the hemispheres being identical. One of such patterns is shown in FIG. 4, which indicates the arrangement of dimples and the relative sizes of the dimples in that particular pattern.
Comparative tests were made using the ball of the present invention and a Spalding TOP-FLITE II ball; results of the tests were as follows:
______________________________________TEST NO. 1CLUB: U.S.G.A. DRIVER/CLUB HEAD SPEED: 160 fpsBALL TYPE TOP-FLITE II BALL OF FIGS. 3 & 4______________________________________Trajectory 10.60 10.40Flight Time 5.90 5.70Carry 249.40 244.20Difference in Carry 0.00 -5.30Deviation -6.14 -2.72Roll 30.60 35.20Total Distance 280.00 279.40Difference in Roll 0.00 -0.70______________________________________
______________________________________TEST NO. 2CLUB: U.S.G.A. DRIVER/CLUB HEAD SPEED: 145 fpsBALL TYPE TOP-FLITE II BALL OF FIGS. 3 & 4______________________________________Trajectory 9.70 9.60Flight Time 5.40 5.20Carry 218.10 214.50Difference in Carry 0.00 -3.60Deviation -6.03 -1.92Roll 32.90 37.90Total Distance 250.90 252.40Difference in Roll -1.50 0.00______________________________________
______________________________________TEST NO. 3CLUB: 5-IRON/CLUB HEAD SPEED: 120 fpsBALL TYPE TOP-FLITE II BALL OF FIGS. 2 & 3______________________________________Trajectory N/A N/AFlight Time 5.90 6.00Carry 165.50 168.00Difference in Carry -3.20 -0.80Deviation -1.58 0.75Roll 12.70 13.20Total Distance 178.20 181.10Difference in Roll 03.00 -0.10______________________________________
The following is a comparison of the ball of the present invention to that of a TOP-FLITE II ball:
______________________________________BALL FIGS. 2 & 3 TOP-FLITE II______________________________________Ball Diameter 1.717 1.685Center Diameter 1.545 1.545Ball Weight (Grams) 45.500 45.500Cover Thickness 0.086 0.070Center Weight (Grams) 34.400 36.470Cover Weight (Grams) 11.100 9.030Cover (Grams/cm.sup.2) 31.897 25.400Center (Grams/cm.sup.2) 52.976 56.200Moment (Grams/cm.sup.2) 84.870 81.600Moment (Ounces/in.sup.2) 0.464 0.446______________________________________
As can be seen, the ball of FIGS. 2 and 3 compares favorably with the TOP-FLITE II as the control ball when a driver is used, but is superior to the control ball when a 5-iron is used. Thus, there is achieved substantially maximum performance while still having a ball that is more easily controlled because of the additional surface of the ball.
It was also determined that the golf ball of the present invention as particularly illustrated in FIGS. 2 and 3 has a lower spin rate in r.p.m. than the standard balls which are in use today. This test is determined by using an automatic driving machine which uses a full 9-iron. The results of this test are as follows:
______________________________________ SPIN RATE RPMBALL TYPE (Average)______________________________________TITLEIST 384 TOUR 100 9,773TOUR EDITION 100 10,905TOUR EDITION 90 10,405TOP-FLITE II 9,501BALL OF FIGS. 2 & 3 9,210______________________________________
The following are the coordinates of the dimple pattern of the ball of FIGS. 2 and 3, indicating dimple location and and diameter for each dimple on one of the hemispheres of the ball:
__________________________________________________________________________DIMPLE LATITUDE LONGITUDE DIMPLENUMBER Degrees Minutes Seconds Degrees Minutes Seconds DIAMETER__________________________________________________________________________1 0 0 0 0 0 0 0.14502 9 42 45 36 0 0 0.14503 9 42 45 108 0 0 0.14504 9 42 45 180 0 0 0.14505 9 42 45 252 0 0 0.14506 9 42 45 324 0 0 0.14507 16 15 45 0 0 0 0.14508 16 15 45 72 0 0 0.14509 16 15 45 144 0 0 0.145010 16 15 45 216 0 0 0.145011 16 15 45 288 0 0 0.145012 19 26 0 36 0 0 0.145013 19 26 0 108 0 0 0.145014 19 26 0 180 0 0 0.145015 19 26 0 252 0 0 0.145016 19 26 0 324 0 0 0.145017 25 18 0 13 26 0 0.145018 25 18 0 58 34 0 0.145019 25 18 0 85 26 0 0.145020 25 18 0 130 34 0 0.145021 25 18 0 157 26 0 0.145022 25 18 0 202 34 0 0.145023 25 18 0 229 26 0 0.145024 25 18 0 274 34 0 0.145025 25 18 0 301 26 0 0.145026 25 18 0 346 34 0 0.145027 29 19 0 36 0 0 0.145028 29 19 0 108 0 0 0.145029 29 19 0 180 0 0 0.145030 29 19 0 252 0 0 0.145031 29 19 0 324 0 0 0.145032 34 33 30 19 50 0 0.145033 34 33 30 52 10 0 0.145034 34 33 30 91 50 0 0.145035 34 33 30 124 10 0 0.145036 34 33 30 163 50 0 0.145037 34 33 30 196 10 0 0.145038 34 33 39 235 50 0 0.145039 34 33 30 268 10 0 0.145040 34 33 30 307 50 0 0.145041 34 33 30 340 10 0 0.145042 36 52 30 0 0 0 0.169043 36 52 30 72 0 0 0.169044 36 52 30 144 0 0 0.169045 36 52 30 216 0 0 0.169046 36 52 30 288 0 0 0.169047 39 2 45 36 0 0 0.145048 39 2 45 108 0 0 0.145049 39 2 45 180 0 0 0.145050 39 2 45 252 0 0 0.145051 39 2 45 324 0 0 0.145052 44 9 30 23 33 15 0.145053 44 9 30 48 26 45 0.145054 44 9 30 95 33 15 0.145055 44 9 30 120 26 45 0.145056 44 9 30 167 33 15 0.145057 44 9 30 192 26 45 0.145058 44 9 30 239 33 15 0.145059 44 9 30 264 26 45 0.145060 44 9 30 311 33 15 0.145061 44 9 30 336 26 45 0.145062 46 50 15 8 34 45 0.169063 46 50 15 63 25 15 0.169064 46 50 15 80 34 45 0.169065 46 50 15 135 25 15 0.169066 46 50 15 152 34 45 0.169067 46 50 15 207 25 15 0.169068 46 50 15 224 34 45 0.169069 46 50 15 279 25 15 0.169070 46 50 15 296 34 45 0.169071 46 50 15 351 25 15 0.169072 48 55 0 36 0 0 0.145073 48 55 0 108 0 0 0.145074 48 55 0 180 0 0 0.145075 48 55 0 252 0 0 0.145076 48 55 0 324 0 0 0.145077 53 50 15 25 15 45 0.145078 53 50 15 46 44 15 0.145079 53 50 15 97 15 45 0.145080 53 50 15 118 44 15 0.145081 53 50 15 169 15 45 0.145082 53 50 15 190 44 15 0.145083 53 50 15 241 15 45 0.145084 53 50 15 262 44 15 0.145085 53 50 15 313 15 45 0.145086 53 50 15 334 44 15 0.145087 56 37 30 0 0 0 0.169088 56 37 30 72 0 0 0.169089 56 37 30 144 0 0 0.169090 56 37 30 216 0 0 0.169091 56 37 30 288 0 0 0.169092 57 12 0 13 39 0 0.157093 57 12 0 58 21 0 0.157094 57 12 0 85 39 0 0.157095 57 12 0 130 21 0 0.157096 57 12 0 157 39 0 0.157097 57 12 0 202 21 0 0.157098 57 12 0 229 39 0 0.157099 57 12 0 274 21 0 0.1570100 57 12 0 301 39 0 0.1570101 57 12 0 346 21 0 0.1570102 58 39 15 36 0 0 0.1450103 58 39 15 108 0 0 0.1450104 58 39 15 180 0 0 0.1450105 58 39 15 252 0 0 0.1450106 58 39 15 324 0 0 0.1450107 63 51 30 26 25 15 0.1450108 63 51 30 45 34 45 0.1450109 63 51 30 98 25 15 0.1450110 63 51 30 117 34 45 0.1450111 63 51 30 170 25 15 0.1450112 63 51 30 189 34 45 0.1450113 63 51 30 242 25 15 0.1450114 63 51 30 261 34 45 0.1450115 63 51 30 314 25 15 0.1450116 63 51 30 333 34 45 0.1450117 66 36 0 5 24 0 0.1450118 66 36 0 66 36 0 0.1450119 66 36 0 77 24 0 0.1450120 66 36 0 138 36 0 0.1450121 66 36 0 149 24 0 0.1450122 66 36 0 210 36 0 0.1450123 66 36 0 221 24 0 0.1450124 66 36 0 282 36 0 0.1450125 66 36 0 293 24 0 0.1450126 66 36 0 354 36 0 0.1450127 67 4 30 16 5 30 0.1450128 67 4 30 55 54 30 0.1450129 67 4 30 88 5 30 0.1450130 67 4 30 127 54 30 0.1450131 67 4 30 160 5 30 0.1450132 67 4 30 199 54 30 0.1450133 67 4 30 232 5 30 0.1450134 67 4 30 271 54 30 0.1450135 67 4 30 304 5 30 0.1450136 67 4 30 343 54 30 0.1450137 68 20 30 36 0 0 0.1450138 68 20 30 108 0 0 0.1450139 68 20 30 180 0 0 0.1450140 68 20 30 252 0 0 0.1450141 68 20 30 324 0 0 0.1450142 75 24 30 0 0 0 0.1450143 75 24 30 72 0 0 0.1450144 75 24 30 144 0 0 0.1450145 75 24 30 216 0 0 0.1450146 75 24 30 288 0 0 0.1450147 75 42 0 10 20 45 0.1450148 75 42 0 61 39 15 0.1450149 75 42 0 82 20 45 0.1450150 75 42 0 133 39 15 0.1450151 75 42 0 154 20 45 0.1450152 75 42 0 205 39 15 0.1450153 75 42 0 226 20 45 0.1450154 75 42 0 277 39 15 0.1450155 75 42 0 298 20 45 0.1450156 75 42 0 349 39 15 0.1450157 76 14 0 20 20 0 0.1450158 76 14 0 51 40 0 0.1450159 76 14 0 92 20 0 0.1450160 76 14 0 123 40 0 0.1450161 76 14 0 164 20 0 0.1450162 76 14 0 195 40 0 0.1450163 76 14 0 236 20 0 0.1450164 76 14 0 267 40 0 0.1450165 76 14 0 308 20 0 0.1450166 76 14 0 339 40 0 0.1450167 76 26 15 30 22 15 0.1450168 76 26 15 41 37 45 0.1450169 76 26 15 102 22 15 0.1450170 76 26 15 113 37 45 0.1450171 76 26 15 174 22 15 0.1450172 76 26 i5 185 37 45 0.1450173 76 26 15 246 22 15 0.1450174 76 26 15 257 37 45 0.1450175 76 26 15 318 22 15 0.1450176 76 26 15 329 37 45 0.1450177 86 1 15 5 8 30 0.1450178 86 1 15 15 25 45 0.1450179 85 1 15 25 42 45 0.1450180 85 1 15 36 0 0 0.1450181 85 1 15 46 17 15 0.1450182 85 1 15 56 34 15 0.1450183 85 1 15 66 51 30 0.1450184 85 1 15 77 8 30 0.1450185 85 1 15 87 25 45 0.1450186 85 1 15 97 42 45 0.1450187 85 1 15 108 0 0 0.1450188 85 1 15 118 17 15 0.1450189 85 1 15 128 34 15 0.1450190 85 1 15 138 51 30 0.1450191 85 1 15 149 8 30 0.1450192 85 1 15 159 25 45 0.1450193 85 1 15 169 42 45 0.1450194 85 1 15 180 0 0 0.1450195 85 1 15 190 17 15 0.1450196 85 1 15 200 34 15 0.1450197 85 1 15 210 51 30 0.1450198 85 1 15 221 8 30 0.1450199 85 1 15 231 25 45 0.1450200 85 1 15 241 42 45 0.1450201 85 1 15 252 0 0 0.1450202 85 1 15 262 17 15 0.1450203 85 1 15 272 34 15 0.1450204 85 1 15 282 51 30 0.1450205 85 1 15 293 8 30 0.1450206 85 1 15 303 25 45 0.1450207 85 1 15 313 42 45 0.1450208 85 1 15 324 0 0 0.1450209 85 1 15 334 17 15 0.1450210 85 1 15 344 34 15 0.1450211 85 1 15 354 51 30 0.1450__________________________________________________________________________
The ball of FIGS. 2, 3 and 4 illustrates that the dimple pattern on the ball is made up of a plurality of triangles 15, 17 and 19 which comprise a modified icosahedron. The dimples are arranged on the ball in order to obtain maximum surface coverage of the ball, with the largest dimples 33, intermediate dimples 35, and smaller dimples 31 being located as shown relative to lines 15, 17, and 19 of the triangles. Lines 21, 23, and 24 are extensions of a further triangle to the equatorial line of the ball. This is the same arrangement of dimples as that of the Spalding TOP-FLITE PLUS II ball shown and described in U. S. patent application Ser. No. 07/384,205, now U.S. Pat. No. 5,018,741 issued May 28, 1991 assigned to the assignee of the present invention. The description and the manner of locating the dimples as set forth in that application is incorporated herein.
A further ball which uses the same basic pattern of FIGS. 2 and 3 and 4 has 10 of the largest diameter dimples, 50 of the intermediate size dimples, and 362 of the smallest diameter dimples. The largest dimple diameter is 0.169 inch with a depth of 0.0123 inch, the intermediate dimple diameter is 0.157 inch with a depth of 0.0123 inch, and the smallest dimple diameter is 0.145 inch with a depth of 0.0101 inch. Thus, the dimple depths of the three different diameter dimples remain the same as the ball of FIGS. 2 and 3. This modification provides a coverage with no dimple overlap while maintaining a 77.4% coverage of the surface area of the ball. The weighted average dimple diameter for this ball is 0.1470 inch and the weighted average dimple depth is 0.0104 inch.
Another ball which uses the same basic pattern of FIGS. 2, 3 and 4 has and 4 10 of the largest diameter dimples, 50 of the intermediate size dimples, and 362 of the smallest diameter dimples. This pattern has a modified dimple diameter wherein the largest diameter is 0.169 inch with a depth of 0.0128 inch, the intermediate dimple diameter is 0.157 inch with a depth of 0.0128 inch, and the smallest dimple diameter is 0.145 inch. In this ball, 222 of the smallest diameter dimples nearest the poles have a depth of 0.0106 inch and the remaining 140 of the smallest diameter dimples have a depth of 0.0096 inch. The remaining intermediate and large diameter dimples have a depth of 0.0128 inch. This modification provides a ball with no dimple overlap while maintaining a 77.4% coverage of the surface area of the ball. The weighted average dimple diameter for this ball is 0.1470 inch and the weighted average dimple depth is 0.01058 inch.
The following are the coordinates for the dimple pattern of the above two balls having 10 large dimples, 50 intermediate dimples, and 362 small dimples:
__________________________________________________________________________DIMPLE LATITUDE LONGITUDE DIMPLENUMBER Degrees Minutes Seconds Degrees Minutes Seconds DIAMETER__________________________________________________________________________1 0 0 0 0 0 0 0.14502 9 42 45 36 0 0 0.1453 9 42 45 108 0 0 0.1454 9 42 45 180 0 0 0.1455 9 42 45 252 0 0 0.1456 9 42 45 324 0 0 0.1457 16 15 45 0 0 0 0.1458 16 15 45 72 0 0 0.1459 16 15 45 144 0 0 0.14510 16 15 45 216 0 0 0.14511 16 15 45 288 0 0 0.14512 19 26 0 36 0 0 0.14513 19 26 0 108 0 0 0.14514 19 26 0 180 0 0 0.14515 19 16 0 252 0 0 0.14516 19 26 0 324 0 0 0.14517 25 18 0 13 26 0 0.14518 25 18 0 58 34 0 0.14519 25 18 0 85 26 0 0.14520 25 18 0 130 34 0 0.14521 25 18 0 157 26 0 0.14522 25 18 0 202 34 0 0.14523 25 18 0 229 26 0 0.14524 25 18 0 274 34 0 0.14525 25 18 0 301 26 0 0.14526 25 18 0 346 34 0 0.14527 29 19 0 36 0 0 0.14528 29 19 0 108 0 0 0.14529 29 19 0 180 0 0 0.14530 29 19 0 252 0 0 0.14531 29 19 0 324 0 0 0.14532 34 33 30 19 50 0 0.14533 34 33 30 52 10 0 0.14534 34 33 30 91 50 0 0.14535 34 33 39 124 10 0 0.14536 34 33 30 163 50 0 0.14537 34 33 30 196 10 0 0.14538 34 33 30 235 50 0 0.14539 34 33 30 268 10 0 0.14540 34 33 30 307 50 0 0.14541 34 33 30 340 10 0 0.14542 38 5 0 0 0 0 0.15743 38 5 0 72 0 0 0.15744 38 5 0 144 0 0 0.15745 38 5 0 216 0 0 0.15746 38 5 0 288 0 0 0.15747 39 2 45 36 0 0 0.14548 39 2 45 108 0 0 0.14549 39 2 45 180 0 0 0.14550 39 2 45 252 0 0 0.14551 39 2 45 324 0 0 0.14552 44 9 30 23 33 15 0.14553 44 9 30 48 26 45 0.14554 44 9 30 95 33 15 0.14555 44 9 30 120 26 45 0.14556 44 9 30 167 33 15 0.14557 44 9 30 192 26 45 0.14558 44 9 30 239 33 15 0.14559 44 8 39 264 26 45 0.14560 44 9 30 311 33 15 0.14561 44 9 30 336 26 45 0.14562 47 33 30 7 34 0 0.15763 47 33 30 64 26 0 0.15764 47 33 30 79 34 0 0.15765 47 33 30 136 26 0 0.15766 47 33 30 151 34 0 0.15767 47 33 30 208 26 0 0.15768 47 33 30 223 34 0 0.15769 47 33 30 280 26 0 0.15770 47 33 30 295 34 0 0.15771 47 33 30 352 26 0 0.15772 48 55 0 36 0 0 0.14573 48 55 0 108 0 0 0.14574 48 55 0 180 0 0 0.14575 48 55 0 252 0 0 0.14576 48 55 0 324 0 0 0.14577 53 50 15 25 15 45 0.14578 53 50 15 46 44 15 0.14579 53 50 15 97 15 45 0.14580 53 50 15 118 44 15 0.14581 53 50 15 169 15 45 0.14582 53 50 15 190 44 15 0.14583 53 50 15 241 15 45 0.14584 53 50 15 262 44 15 0.14585 53 50 15 313 15 45 0.14586 53 50 15 334 44 15 0.14587 57 12 0 13 39 0 0.15788 57 12 0 58 21 0 0.15789 57 12 0 85 39 0 0.15790 57 12 0 130 21 0 0.15791 57 12 0 157 39 0 0.15792 57 12 0 202 21 0 0.15793 57 12 0 229 39 0 0.15794 57 12 0 274 21 0 0.15795 57 12 0 301 39 0 0.15796 57 12 0 346 21 0 0.15797 58 35 15 0 0 0 0.16998 58 35 15 72 0 0 0.16999 58 35 15 144 0 0 0.169100 58 35 15 216 0 0 0.169101 58 35 15 288 0 0 0.169102 58 39 15 36 0 0 0.145103 58 39 15 108 0 0 0.145104 58 39 15 180 0 0 0.145105 58 39 15 252 0 0 0.145106 58 39 15 324 0 0 0.145107 63 51 30 26 25 15 0.145108 63 51 30 45 34 45 0.145109 63 51 30 98 25 15 0.145110 63 51 30 117 34 45 0.145111 63 51 30 170 25 15 0.145112 63 51 30 189 34 45 0.145113 63 51 30 242 25 15 0.145114 63 51 30 261 34 45 0.145115 63 51 30 314 25 15 0.145116 63 51 30 333 34 45 0.145117 67 4 30 16 5 30 0.145118 67 4 30 55 54 30 0.145119 67 4 30 88 5 30 0.145120 67 4 30 127 54 30 0.145121 67 4 30 160 5 30 0.145122 67 4 30 199 54 30 0.145123 67 4 30 232 5 30 0.145124 67 4 30 271 54 30 0.145125 67 4 30 304 5 30 0.145126 67 4 30 343 54 30 0.145127 67 56 0 5 39 0 0.145128 67 56 0 66 21 0 0.145129 67 56 0 77 39 0 0.145130 67 56 0 138 21 0 0.145131 67 56 0 149 39 0 0.145132 67 56 0 210 21 0 0.145133 67 56 0 221 39 0 0.145134 67 56 0 282 21 0 0.145135 67 56 0 283 39 0 0.145136 67 56 0 354 21 0 0.145137 68 20 30 36 0 0 0.145138 68 20 30 108 0 0 0.145139 68 20 30 180 0 0 0.145140 68 20 30 252 0 0 0.145141 68 20 30 324 0 0 0.145142 76 14 0 20 20 0 0.145143 76 14 0 51 40 0 0.145144 76 14 0 92 20 0 0.145145 76 14 0 123 40 0 0.145146 76 14 0 164 20 0 0.145147 76 14 0 195 40 0 0.145148 76 14 0 236 20 0 0.145149 76 14 0 267 40 0 0.145150 76 14 0 308 20 0 0.145151 76 14 0 339 40 0 0.145152 76 25 45 0 0 0 0.145153 76 25 45 72 0 0 0.145154 76 25 45 144 0 0 0.145155 76 25 45 216 0 0 0.145156 76 25 45 288 0 0 0.145157 76 26 15 30 22 15 0.145158 76 26 15 41 37 45 0.145159 76 26 15 102 22 15 0.145160 76 26 15 113 37 45 0.145161 76 26 15 174 22 15 0.145162 76 26 15 185 37 45 0.145163 76 26 15 246 22 15 0.145164 76 26 15 257 37 45 0.145165 76 26 15 318 22 15 0.145166 76 26 15 329 37 45 0.145167 76 42 45 10 18 0 0.145168 76 42 45 82 18 0 0.145169 76 42 45 154 18 0 0.145170 76 42 45 226 18 0 0.145171 76 42 45 298 18 0 0.145172 76 43 15 61 42 0 0.145173 76 43 15 133 42 0 0.145174 76 43 15 205 42 0 0.145175 76 43 15 277 42 0 0.145176 76 43 15 349 42 0 0.145177 85 1 15 5 8 30 0.145178 85 1 15 15 25 45 0.145179 85 1 15 25 42 45 0.145180 85 1 15 36 0 0 0.145181 85 1 15 46 17 15 0.145182 85 1 15 56 34 15 0.145183 85 1 15 66 51 30 0.145184 85 1 15 77 8 30 0.145185 85 1 15 87 25 45 0.145186 85 1 15 97 42 45 0.145187 85 1 15 108 0 0 0.145188 85 1 15 118 17 15 0.145189 85 1 15 128 34 15 0.145190 85 1 15 138 51 30 0.145191 85 1 15 149 8 30 0.145192 85 1 15 159 25 45 0.145193 85 1 15 169 42 45 0.145194 85 1 15 180 0 0 0.145195 85 1 15 190 17 15 0.145196 85 1 15 200 34 15 0.145197 85 1 15 210 51 30 0.145198 &5 1 15 221 8 30 0.145199 85 1 15 231 25 45 0.145200 85 1 15 241 42 45 0.145201 85 1 15 252 0 0 0.145202 85 1 15 262 17 15 0.145203 85 1 15 272 34 15 0.145204 85 1 15 282 51 30 0.145205 85 1 15 293 8 30 0.145206 85 1 15 303 25 45 0.145207 85 1 15 313 42 45 0.145208 85 1 15 324 0 0 0.145209 85 1 15 334 17 15 0.145210 85 1 15 344 34 15 0.145211 85 1 15 354 51 30 0.145__________________________________________________________________________
Yet another ball which uses the same basic pattern and dimple diameter of FIGS. 2 and 3 is modified as to dimple depth. The dimples on this ball have the same coordinates as the ball of FIGS. 2 and 3. In this ball, 222 of the smallest diameter dimples nearest the poles have a depth of 0.0106 inch and the remaining 140 of the smallest diameter dimples have a depth of 0.0096 inch. This modification provides a coverage with no dimple overlap while maintaining 78.4% coverage of the surface area of the ball. The weighted average dimple diameter for this ball is 0.1478 inch and the weighted average dimple depth is 0.01058 inch.
A further modification is shown in FIG. 5. This golf ball has 410 dimples comprising 138 dimples having a diameter of 0.169 inch and a depth of 0.0116 inch, 160 dimples having a diameter of 0.143 inch and a depth of 0.0101 inch, and 112 dimples having a diameter of 0.112 inch and a depth of 0.0077 inch. The configuration of the dimples comprises a dimple-free equatorial line E--E dividing the ball into two hemispheres having substantially identical dimple patterns. The dimple pattern of each hemisphere comprises a first plurality of dimples extending in four spaced clockwise arcs between the pole and the equator of each hemisphere, a second plurality of dimples extending in four spaced counterclockwise arcs between the pole and equator of each hemisphere, and a third plurality of dimples filling the surface area between the first and second plurality of dimples. In this ball, none of the dimples overlap. This pattern provides a weighted average dimple diameter of 0.1433 inch, a weighted average dimple depth of 0.010 inch, and a 73.1% coverage of the surface of the ball.
The following are the coordinates of the 410 dimple pattern ball:
__________________________________________________________________________DIMPLE LATITUDE LONGITUDE DIMPLENUMBER Degrees Minutes Seconds Degrees Minutes Seconds DIAMETER__________________________________________________________________________1 0 0 0 0 0 0 0.1692 11 53 30 0 0 0 0.1123 11 53 30 45 0 0 0.1434 11 53 30 90 0 0 0.1125 11 53 30 135 0 0 0.1436 11 53 30 180 0 0 0.1127 11 53 30 225 0 0 0.1438 11 53 30 270 0 0 0.1129 11 53 30 315 0 0 0.14310 18 32 0 19 6 45 0.11211 18 32 0 70 53 15 0.11212 18 32 0 109 6 45 0.11213 18 32 0 160 53 15 0.11214 18 32 0 199 6 45 0.11215 18 32 0 250 53 15 0.11216 18 32 0 289 6 45 0.11217 18 32 0 340 53 15 0.11218 22 24 0 45 0 0 0.16919 22 24 0 135 0 0 0.16920 22 24 0 225 0 0 0.16921 22 24 0 315 0 0 0.16922 23 27 45 0 0 0 0.11223 23 27 45 90 0 0 0.11224 23 27 45 180 0 0 0.11225 23 27 45 270 0 0 0.11226 28 45 15 25 39 0 0.14327 28 45 15 64 21 0 0.14328 28 45 15 115 39 0 0.14329 28 45 15 154 21 0 0.14330 28 45 15 205 39 0 0.14331 28 45 15 244 21 0 0.14332 28 45 15 295 39 0 0.14333 28 45 15 334 21 0 0.14334 30 53 45 8 17 0 0.11235 30 53 45 81 43 0 0.11236 30 53 45 98 17 0 0.11237 30 53 45 171 43 0 0.11238 30 53 45 188 17 0 0.11239 30 53 45 261 43 0 0.11240 30 53 45 278 17 0 0.11241 30 53 45 351 43 0 0.11242 33 55 45 45 0 0 0.16943 33 55 45 135 0 0 0.16944 33 55 45 225 0 0 0.16945 33 55 45 315 0 0 0.16946 37 40 15 0 0 0 0.11247 37 40 15 90 0 0 0.11248 37 40 15 180 0 0 0.11249 37 40 15 270 0 0 0.11250 38 13 15 28 43 0 0.14351 38 13 15 61 17 0 0.14352 38 13 15 118 43 0 0.14353 38 13 15 151 17 0 0.14354 38 13 15 208 43 0 0.14355 38 13 15 241 17 0 0.14356 38 13 15 298 43 0 0.14357 38 13 15 331 17 0 0.14358 41 7 30 13 57 0 0.14359 41 7 30 76 3 0 0.14360 41 7 30 103 57 0 0.14361 41 7 30 166 3 0 0.14362 41 7 30 193 57 0 0.14363 41 7 30 256 3 0 0.14364 41 7 30 283 57 0 0.14365 41 7 30 346 3 0 0.14366 44 31 0 39 0 15 0.11267 44 31 0 50 59 45 0.11268 44 31 0 129 0 15 0.11269 44 31 0 140 59 45 0.11270 44 31 0 219 0 15 0.11271 44 31 0 230 59 45 0.11272 44 31 0 309 0 15 0.11273 44 31 0 320 59 45 0.11274 47 47 15 0 0 0 0.14375 47 47 15 90 0 0 0.14376 47 47 15 180 0 0 0.14377 47 47 15 270 0 0 0.14378 49 27 0 21 28 45 0.14379 49 27 0 68 31 15 0.14380 49 27 0 111 28 45 0.14381 49 27 0 158 31 15 0.14382 49 27 0 201 28 45 0.14383 49 27 0 248 31 15 0.14384 49 27 0 291 28 45 0.14385 49 27 0 338 31 15 0.14386 52 21 45 33 13 15 0.14387 52 21 45 56 46 45 0.14388 52 21 45 123 13 15 0.14389 52 21 45 146 46 45 0.14390 52 21 45 213 13 15 0.14391 52 21 45 236 46 45 0.14392 52 21 45 303 13 15 0.14393 52 21 45 326 46 45 0.14394 53 30 15 10 15 45 0.14395 53 30 15 79 44 15 0.14396 53 30 15 100 15 45 0.14397 53 30 15 169 44 15 0.14398 53 30 15 190 15 45 0.14399 53 30 15 259 44 15 0.143100 53 30 15 280 15 45 0.143101 53 30 15 349 44 15 0.143102 56 28 15 45 0 0 0.169103 56 28 15 135 0 0 0.169104 56 28 15 225 0 0 0.169105 56 28 15 315 0 0 0.169106 58 51 0 0 0 0 0.143107 58 51 0 90 0 0 0.143108 58 51 0 180 0 0 0.143109 58 51 0 270 0 0 0.143110 61 8 30 24 2 0 0.169111 61 8 30 65 58 0 0.169112 61 8 30 114 2 0 0.169113 61 8 30 155 58 0 0.169114 61 8 30 204 2 0 0.169115 61 8 30 245 58 0 0.169116 61 8 30 294 2 0 0.169117 61 8 30 335 58 0 0.169118 64 13 0 11 20 30 0.169119 64 13 0 78 39 30 0.169120 64 13 0 101 20 30 0.169121 64 13 0 168 39 30 0.169122 64 13 0 191 20 30 0.169123 64 13 0 258 39 30 0.169124 64 13 0 281 20 30 0.169125 64 13 0 348 39 30 0.169126 65 4 15 34 34 15 0.112127 65 4 15 55 25 45 0.112128 65 4 15 124 34 15 0.112129 65 4 15 145 25 45 0.112130 65 4 15 214 34 15 0.112131 65 4 15 235 25 45 0.112132 65 4 15 304 34 15 0.112133 65 4 15 325 25 45 0.112134 67 50 15 45 0 0 0.169135 67 50 15 135 0 0 0.169136 67 50 15 225 0 0 0.169137 67 50 15 315 0 0 0.169138 69 25 30 0 0 0 0.143139 69 25 30 90 0 0 0.143140 69 25 30 180 0 0 0.143141 69 25 30 270 0 0 0.143142 72 42 30 21 18 0 0.169143 72 42 30 68 42 0 0.169144 72 42 30 111 18 0 0.169145 72 42 30 158 42 0 0.169146 72 42 30 201 18 0 0.169147 72 42 30 248 42 0 0.169148 72 42 30 291 18 0 0.169149 72 42 30 338 42 0 0.169150 74 42 0 33 5 0 0.169151 74 42 0 56 55 0 0.169152 74 42 0 123 5 0 0.169153 74 42 0 146 55 0 0.169154 74 42 0 213 5 0 0.169155 74 42 0 236 55 0 0.169156 74 42 0 303 5 0 0.169157 74 42 0 326 55 0 0.169158 75 34 0 9 26 30 0.169159 75 34 0 80 33 30 0.169160 75 34 0 99 26 30 0.169161 75 34 0 170 33 30 0.169162 75 34 0 189 26 30 0.169163 75 34 0 260 33 30 0.169164 75 34 0 279 26 30 0.169165 75 34 0 350 33 30 0.169166 79 8 15 45 0 0 0.169167 79 8 15 135 0 0 0.169168 79 8 15 225 0 0 0.169169 79 8 15 315 0 0 0.169170 79 18 0 0 0 0 0.112171 79 18 0 90 0 0 0.112172 79 18 0 180 0 0 0.112173 79 18 0 270 0 0 0.112174 83 47 15 24 36 45 0.169175 83 47 15 65 23 15 0.169176 83 47 15 114 36 45 0.169177 83 47 15 155 23 15 0.169178 83 47 15 204 36 45 0.169179 83 47 15 245 23 15 0.169180 83 47 15 294 36 45 0.169181 83 47 15 335 23 15 0.169182 84 46 45 35 54 15 0.143183 84 46 45 54 5 45 0.143184 84 46 45 125 54 15 0.143185 84 46 45 144 5 45 0.143186 84 46 45 215 54 15 0.143187 84 46 45 234 5 45 0.143188 84 46 45 305 54 15 0.143189 84 46 45 324 5 45 0.143190 85 0 15 14 6 30 0.143191 85 0 15 75 53 30 0.143192 85 0 15 104 6 30 0.143193 85 0 15 165 53 30 0.143194 85 0 15 194 6 30 0.143195 85 0 15 255 53 30 0.143196 85 0 15 284 6 30 0.143197 85 0 15 345 53 30 0.143198 85 39 15 4 54 15 0.112199 85 39 15 85 5 45 0.112200 85 39 15 94 54 15 0.112201 85 39 15 175 5 45 0.112202 85 39 15 184 54 15 0.112203 85 39 15 265 5 45 0.112204 85 39 15 274 54 15 0.112205 85 39 15 355 5 45 0.112__________________________________________________________________________
A still further modification is shown in FIG. 6. This golf ball has 422 dimples, all dimples having the same diameter of 0.143 inch and the same depth of 0.0103 inch. The dimples are arranged in a configuration so as to provide dimple-free equatorial line, with each hemisphere of the ball having six identical dimpled substantially mating sections with a common dimple at each pole. FIG. 6 shows two mating sections having dimples 1 and 2, respectively. Each section comprises six dimples lying substantially along a line parallel with but spaced from the equatorial line, 29 dimples between the six dimples and the common polar dimple, with the outer dimples of each of said sections lying on modified sinusoidal lines 113 and 115.
Since only one diameter is used for all dimples, some small percentage of overlap occurs in order to provide substantial surface coverage with the dimples. For this particular pattern, there is an 11.4% (48) dimple overlap with a 73.2% coverage of the surface area of the ball. Overlap is determined by finding the number of dimples having an edge overlapping any other dimple and dividing that number by the total number of dimples on the ball, such number being expressed as a percentage.
The following are the coordinates for the dimple pattern of the 422 dimple ball having one size of dimples:
__________________________________________________________________________DIMPLE LATITUDE LONGITUDE DIMPLENUMBER Degrees Minutes Seconds Degrees Minutes Seconds DIAMETER__________________________________________________________________________1 0 0 0 30 0 0 0.1432 10 25 0 30 0 0 0.1433 10 25 0 90 0 0 0.1434 10 25 0 150 0 0 0.1435 10 25 0 210 0 0 0.1436 10 25 0 270 0 0 0.1437 10 25 0 330 0 0 0.1438 18 17 45 0 0 0 0.1439 18 17 45 60 0 0 0.14310 18 17 45 120 0 0 0.14311 18 17 45 180 0 0 0.14312 18 17 45 240 0 0 0.14313 18 17 45 300 0 0 0.14314 20 49 45 30 0 0 0.14315 20 49 45 90 0 0 0.14316 20 49 45 150 0 0 0.14317 20 49 45 210 0 0 0.14318 20 49 45 270 0 0 0.14319 20 49 45 330 0 0 0.14320 27 43 15 49 19 0 0.14321 27 43 15 109 19 0 0.14322 27 43 15 169 19 0 0.14323 27 43 15 229 19 0 0.14324 27 43 15 289 19 0 0.14325 27 43 15 349 19 0 0.14326 27 43 30 10 40 45 0.14327 27 43 30 70 40 45 0.14328 27 43 30 130 40 45 0.14329 27 43 30 190 40 45 0.14330 27 43 30 250 40 45 0.14331 27 43 30 310 40 45 0.14332 30 48 45 30 0 0 0.14333 30 48 45 90 0 0 0.14334 30 48 45 150 0 0 0.14335 30 48 45 210 0 0 0.14336 30 48 45 270 0 0 0.14337 30 48 45 330 0 0 0.14338 39 25 30 7 34 30 0.14339 39 25 30 52 25 30 0.14340 39 25 30 67 34 30 0.14341 39 25 30 112 25 30 0.14342 39 25 30 127 34 30 0.14343 39 25 30 172 25 30 0.14344 39 25 30 187 34 30 0.14345 39 25 30 232 25 30 0.14346 39 25 30 247 34 30 0.14347 39 25 30 292 25 30 0.14348 39 25 30 307 34 30 0.14349 39 25 30 352 25 30 0.14350 39 39 15 22 13 30 0.14351 39 39 15 82 13 30 0.14352 39 39 15 142 13 30 0.14353 39 39 15 202 13 30 0.14354 39 39 15 262 13 30 0.14355 39 39 15 322 13 30 0.14356 39 39 15 37 46 30 0.14357 39 39 15 97 46 30 0.14358 39 39 15 157 46 30 0.14359 39 39 15 217 46 30 0.14360 39 39 15 277 46 30 0.14361 39 39 15 337 46 30 0.14362 48 35 15 13 42 45 0.14363 48 35 15 46 17 15 0.14364 48 35 15 73 42 45 0.14365 48 35 15 106 17 15 0.14366 48 36 15 133 42 45 0.14367 48 35 15 166 17 15 0.14368 48 35 15 193 42 45 0.14369 48 35 15 226 17 15 0.14370 48 35 15 253 42 45 0.14371 48 35 15 286 17 15 0.14372 48 35 15 313 42 45 0.14373 48 35 15 346 17 15 0.14374 49 19 0 60 0 0 0.14375 49 19 0 120 0 0 0.14376 49 19 0 180 0 0 0.14377 49 19 0 240 0 0 0.14378 49 19 0 300 0 0 0.14379 49 19 0 360 0 0 0.14380 49 40 30 30 0 0 0.14381 49 40 30 90 0 0 0.14382 49 40 30 150 0 0 0.14383 49 40 30 210 0 0 0.14384 49 40 30 270 0 0 0.14385 49 40 30 330 0 0 0.14386 58 1 30 18 41 30 0.14387 58 1 30 41 18 30 0.14388 58 1 30 78 41 30 0.14389 58 1 30 101 18 30 0.14390 58 1 30 138 41 30 0.14391 58 1 30 161 18 30 0.14392 58 1 30 198 41 30 0.14393 58 1 30 221 18 30 0.14394 58 1 30 258 41 30 0.14395 58 1 30 281 18 30 0.14396 58 1 30 318 41 30 0.14397 58 1 30 341 18 30 0.14398 58 14 15 6 6 15 0.14399 58 14 15 53 53 45 0.143100 58 14 15 66 6 15 0.143101 58 14 15 113 53 45 0.143102 58 14 15 126 6 15 0.143103 58 14 15 173 53 45 0.143104 58 14 15 186 6 15 0.143105 58 14 15 233 53 45 0.143106 58 14 15 246 6 15 0.143107 58 14 15 293 53 45 0.143108 58 14 15 306 6 15 0.143109 58 14 15 353 53 45 0.143110 60 8 15 30 0 0 0.143111 60 8 15 90 0 0 0.143112 50 8 15 150 0 0 0.143113 60 8 15 210 0 0 0.143114 60 8 15 270 0 0 0.143115 60 8 15 330 0 0 0.143116 67 3 0 11 19 15 0.143117 67 3 0 48 40 45 0.143118 67 3 0 71 19 15 0.143119 67 3 0 108 40 45 0.143120 67 3 0 131 19 15 0.143121 67 3 0 168 40 45 0.143122 67 3 0 191 19 15 0.143123 67 3 0 228 40 45 0.143124 67 3 0 251 19 15 0.143125 67 3 0 288 40 45 0.143126 67 3 0 311 19 15 0.143127 67 3 0 348 40 45 0.143128 67 15 45 0 0 0 0.143129 67 15 45 60 0 0 0.143130 67 15 45 120 0 0 0.143131 67 15 45 180 0 0 0.143132 67 15 45 240 0 0 0.143133 67 15 45 300 0 0 0.143134 67 39 30 22 36 30 0.143135 67 39 30 37 23 30 0.143136 67 39 30 82 36 30 0.143137 67 39 30 97 23 30 0.143138 67 39 30 142 36 30 0.143139 67 39 30 157 23 30 0.143140 67 39 30 202 36 30 0.143141 67 39 30 217 23 30 0.143142 67 39 30 262 36 30 0.143143 67 39 30 277 23 30 0.143144 67 39 30 322 36 30 0.143145 67 39 30 337 23 30 0.143146 74 20 30 30 0 0 0.143147 74 20 30 90 0 0 0.143148 74 20 30 150 0 0 0.143149 74 20 30 210 0 0 0.143150 74 20 30 270 0 0 0.143151 74 20 30 330 0 0 0.143152 75 54 0 5 20 45 0.143153 75 54 0 54 39 15 0.143154 75 54 0 65 20 45 0.143155 75 54 0 114 39 15 0.143156 75 54 0 125 20 45 0.143157 75 54 0 174 39 15 0.143158 75 54 0 185 20 45 0.143159 75 54 0 234 39 15 0.143160 75 54 0 245 20 45 0.143161 75 54 0 294 39 15 0.143162 75 54 0 305 20 45 0.143163 75 54 0 354 39 15 0.143164 75 57 0 16 16 30 0.143165 75 57 0 43 43 30 0.143166 75 57 0 76 16 30 0.143167 75 57 0 103 43 30 0.143168 75 57 0 136 16 30 0.143169 75 57 0 163 43 30 0.143170 75 57 0 196 16 30 0.143171 75 57 0 223 43 30 0.143172 75 57 0 256 16 30 0.143173 75 57 0 283 43 30 0.143174 75 57 0 316 16 30 0.143175 75 57 0 343 43 30 0.143176 84 17 45 0 0 0 0.143177 84 17 45 30 0 0 0.143178 84 17 45 60 0 0 0.143179 84 17 45 90 0 0 0.143180 84 17 45 120 0 0 0.143181 84 17 45 150 0 0 0.143182 84 17 45 180 0 0 0.143183 84 17 45 210 0 0 0.143184 84 17 45 240 0 0 0.143185 84 17 45 270 0 0 0.143186 84 17 45 300 0 0 0.143187 84 17 45 330 0 0 0.143188 84 19 45 10 17 30 0.143189 84 19 45 49 42 30 0.143190 84 19 45 70 17 30 0.143191 84 19 45 109 42 30 0.143192 84 19 45 130 17 30 0.143193 84 19 45 169 42 30 0.143194 84 19 45 190 17 30 0.143195 84 19 45 229 42 30 0.143196 84 19 45 250 17 30 0.143197 84 19 45 289 42 30 0.143198 84 19 45 310 17 30 0.143199 84 19 45 349 42 30 0.143200 85 1 15 20 9 30 0.143201 85 1 15 39 50 30 0.143202 85 1 15 80 9 30 0.143203 85 1 15 99 50 30 0.143204 85 1 15 140 9 30 0.143205 85 1 15 159 50 30 0.143206 85 1 15 200 9 30 0.143207 85 1 15 219 50 30 0.143208 85 1 15 260 9 30 0.143209 85 1 15 279 50 30 0.143210 85 1 15 320 9 30 0.143211 85 1 15 339 50 30 0.143__________________________________________________________________________
In addition to the advantages discussed above, there is easier access to the ball with the club in both the fairway and rough because of the ball's size. This easier access allows for cleaner hits. Further, the increased size and moment results in the ball's ability to hold the line during putting. Thus, by increasing the percentage of dimple coverage of the surface of the ball, the ball has the advantages attributable to the larger ball while having enhanced flight characteristics as compared to previous balls having enlarged diameters.
The above description and drawings are illustrative only since obvious 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 two-piece golf ball of improved playing characteristics comprising
  • a core having a weight of substantially 34.4 grams;
  • a cover having a weight of substantially 11.1 grams;
  • said ball having a total weight of no more than 46.0 grams;
  • a dimple pattern comprising a plurality of dimples on the surface of said ball;
  • said dimple pattern covering at least 70.0% of the surface of said ball.
Parent Case Info

This application is a division of pending application Ser. No. 08/171,956, filed Dec. 22, 1993 which is a continuation of application Ser. No. 07/800,198 filed Nov. 27, 1991, now U.S. Pat. No. 5,273,287 issued Dec. 28, 1995.

US Referenced Citations (129)
Number Name Date Kind
RE25427 Harkins Jul 1963
D107066 Cavignac Nov 1937
D228394 Martin et al. Sep 1973
D243866 Shaw et al. Mar 1977
D247685 Haines et al. Apr 1978
878254 Taylor Feb 1908
906932 Riblet Dec 1908
922773 Kempshall May 1909
985741 Harvey Feb 1911
1182605 Wadsworth May 1916
1265036 Bendelow Jul 1918
1286834 Taylor Dec 1918
1418220 White May 1922
1482232 Hazeltine Jan 1924
1656408 Young Jan 1928
1666699 Hagen Apr 1928
1681167 Beldam Aug 1928
1716435 Fotheringham Jun 1929
1855448 Hazeltine Apr 1932
2002726 Young May 1935
2106704 Davis Feb 1938
2643125 Juve Jun 1953
2728576 Martin et al. Dec 1955
2730159 Semegen Jan 1956
2741480 Smith Apr 1956
2861810 Veatch Nov 1958
2997302 Smith Aug 1961
3031194 Strayer Apr 1962
3819190 Nepela et al. Jun 1974
3940145 Gentiluomo Feb 1976
4090716 Martin et al. May 1978
4141559 Melvin et al. Feb 1979
4142727 Shaw Mar 1979
4201384 Barber May 1980
4235441 Ciccarello Nov 1980
4256304 Smith et al. Mar 1981
4258921 Worst Mar 1981
4266773 Treadwell May 1981
4284276 Worst Aug 1981
4346898 Badke Aug 1982
4560168 Aoyama Dec 1985
4653758 Solheim Mar 1987
4660834 Carrigan Apr 1987
4681323 Alaki et al. Jul 1987
4720111 Yamada Jan 1988
4722529 Shaw et al. Feb 1988
4729567 Oka et al. Mar 1988
4729861 Lynch et al. Mar 1988
4744564 Yamada May 1988
4762326 Gobush Aug 1988
4765626 Gobush Aug 1988
4772026 Gobush Sep 1988
4787638 Kobayashi Nov 1988
4804189 Gobush Feb 1989
4813677 Oka et al. Mar 1989
4830378 Aoyama May 1989
4840381 Ihara et al. Jun 1989
4844472 Ihara Jul 1989
4848766 Oka et al. Jul 1989
4858923 Gobush et al. Aug 1989
4867459 Ihara Sep 1989
4869512 Nomura et al. Sep 1989
4877252 Shaw Oct 1989
4880241 Melvin et al. Nov 1989
4886277 Mackey Dec 1989
4915389 Ihara Apr 1990
4915390 Gobush et al. Apr 1990
4921255 Taylor May 1990
4925193 Melvin et al. May 1990
4932664 Pocklington et al. Jun 1990
4936587 Lynch et al. Jun 1990
4949976 Gobush Aug 1990
4960282 Shaw Oct 1990
4960283 Gobush Oct 1990
4968038 Yamada Nov 1990
4971330 Morell Nov 1990
4973057 Morell Nov 1990
4974853 Morell Dec 1990
4974854 Morell Dec 1990
4974855 Morell Dec 1990
4974856 Morell Dec 1990
4979747 Jonkouski Dec 1990
4982964 Morell Jan 1991
4991852 Pattison Feb 1991
4998733 Lee Mar 1991
5009427 Stiefel et al. Apr 1991
5009428 Yamagishi et al. Apr 1991
5016887 Jonkouski May 1991
5018741 Stiefel et al. May 1991
5024444 Yamagishi et al. Jun 1991
5033750 Yamagishi et al. Jul 1991
5044638 Nesbitt et al. Sep 1991
5046742 Mackey Sep 1991
5060953 Bunger et al. Oct 1991
5060954 Gobush Oct 1991
5062644 Lee Nov 1991
5064199 Morell Nov 1991
5072945 Oka et al. Dec 1991
5078402 Oka Jan 1992
5080367 Lynch et al. Jan 1992
5087048 Sun et al. Feb 1992
5087049 Yamagishi et al. Feb 1992
5090705 Oka et al. Feb 1992
5092604 Oka Mar 1992
5106096 Dunn Apr 1992
5123652 Oka Jun 1992
5127655 Yamada et al. Jul 1992
5143377 Oka et al. Sep 1992
5145180 Oka Sep 1992
5149100 Melvin et al. Sep 1992
5156404 Oka et al. Oct 1992
5158300 Aoyama Oct 1992
5174578 Oka et al. Dec 1992
5190294 Oka Mar 1993
5192078 Woo Mar 1993
5192079 Sun et al. Mar 1993
5201522 Pocklington et al. Apr 1993
5209485 Nesbitt et al. May 1993
5249804 Sanchez Oct 1993
5253872 Lemons et al. Oct 1993
5259624 Puckett Nov 1993
5273287 Molitor et al. Dec 1993
5292132 Oka Mar 1994
5301951 Morell Apr 1994
5308076 Sun May 1994
5332226 Kim Jul 1994
5338039 Oka et al. Aug 1994
5356150 Lavallee Oct 1994
5503397 Molitor et al. Apr 1996
Foreign Referenced Citations (10)
Number Date Country
192618 Jan 1983 NZX
4774 Mar 1892 GBX
4360 Feb 1898 GBX
20778 Sep 1911 GBX
3012 Feb 1912 GBX
22179 Sep 1912 GBX
645 Jan 1914 GBX
189551 Sep 1921 GBX
377354 May 1931 GBX
420410 Jan 1934 GBX
Divisions (1)
Number Date Country
Parent 171956 Dec 1993
Continuations (1)
Number Date Country
Parent 800198 Nov 1991