Racquetball racquet with increased hitting area improved racquetball racquet construction

Abstract

The improved racquetball racquet has a strung surface which is larger in area than the strung surface of a conventional racquet, and in which the strung area is both longer in length and width than the strung area of a conventional racquet. However, the overall weight and balance of a conventional racquet which has proven necessary for good playing characteristics for all such racquets have been maintained. The racquet has synergistically combined the weight of the racquet, the center of mass of the racquet, the stiffness of the frame, and the response characteristics to create a racquet of sufficient durability with a larger "sweet spot" to facilitate the playing of the sport and to increase the level of skill, particularly of the novice and intermediate players. The racquet has an overall length of 181/2 inches to 221/2 inches and a frame and strung surface width of 12 91/2 inches to 143/4 111/2 inches, a weight of 220 grams to 270 grams, and a center of gravity at a location within a range of 3/4 inch toward the handle and 1/2 inch toward the head as measured from the longitudinal center point of the racquet.

Description

, stringing pattern,, as well as frame 6, are formed with a plurality of holes, one of which is illustrated at 12, for receiving strings 13 therethrough, which form the pattern for strung area 11. A plastic grommet strip 15 preferably extends around the outer edge 16 of frame 6 to reduce the abrasive action of strings 11 13 against frame 6 when repeatedly struck by a ball to increase the life of the strings. Grommet strip 15 is mounted in a channel 17 formed by frame edges 16 (FIG. 2). Strings 13 are of a usual construction, preferably formed of nylon or other synthetic or composite material although animal gut could be used if desired.

The number of strings 13 which form strung area 11 consists of a plurality of longitudinally extending strings 19 and a plurality of transversely extending strings 20 interwoven with strings 19 in a the usual manner. The number of strings 19 and 20 may vary depending upon the final size of the racquet. In the preferred racquet shown in the drawings, strung area 11 consists of longitudinal strings 19 and transversely extending strings 20.

In accordance with one of the features of the invention, improved racquet 1 will have a strung area considerably larger than that of a conventional racquetball racquet. The overall length of racquet 1 will be between 181/2 and 221/2 inches, preferably 201/2 inches (a conventional racquet being 18 to 19 inches). Furthermore, the weight of the racquet will be between 220 grams and 270 grams. Preferably, the improved racquet will weigh between 240 and 250 grams which again is the conventional weight range of a usual racquetball racquet. By maintaining the same overall balance and weight of the conventional racquetball racquet, a player will not have to become accustomed to a completely different feel of the racquet, yet will achieve the greater results of the increased ball striking area provided by strung area 11.

The following data should be noted:

A. Radar gun tests, using accomplished players show consistently 10 percent higher ball velocities than conventional racquets for the following reasons: (1) The center of percussion is approximately 1.4 inches (10 percent) closer to the impact point (see FIGS. 5 and 6); (2) Longitudinal moment of inertia is approximately 30 percent higher (50 to 90 g in sec² vs. 35 to 70); and (3) main and cross strings, in the impact zone, are 30 to 40 percent longer (13 inches and 9.5 inches vs. 9.5 inches and 7.1 inches).

B. Players feel that off-center mishit or reaction shots get to the front wall with more authority for the same reasons as noted in (A) immediately above, plus (1) rotational moment of inertia is about 100 percent higher than conventional frames (4.8 g in sec² vs. 2.4); and (2) the "sweet spot" area is over 30 percent greater. See "sweet spot" comparisons in FIGS. 5 and 6.

C. Players get better court coverage and more reach because the racquet is over 10 percent longer and nearly 40 percent wider than conventional frames.

The width of the racquet 1 or the outside distance between the frame edges of head 2 is between 91/2 inches and 111/2 inches in the direction perpendicular to the longitudinal axis of the racquet which is indicated at 22 in FIG. 4. The preferable width is 101/2 inches.

The center of gravity 23a of racquet 1 is at a location within a range of 3/4 inch toward the hand handle grip 4 and 1/2 inch toward the racquet head as measured from the longitudinal center point of the racquet indicated at 23 in FIG. 4.

In accordance with another feature of the invention, improved racquetball racquet 1 has a generally flattened outer end for head 2, to enable the larger string area to get closer to the court walls and into the corners for hitting the ball in these heretofore tight areas. Head 2 which has the generally oval oblong configuration, has a minor axis 25 (FIG. 4) which intersects major axis 26 which lies on the longitudinal axis 22 of the racquet. The arc 27 which is subtended by minor axis 25 consists of three arcuate sections, comprised of two outer sections 28 and 29 and a center section 30. Center section 30 has an arcuate length of approximately 10 degrees and is defined by a radius line indicated at 31, the center point of which is indicated at 32.

The arcuate lengths of outer sections 28 and 29 are approximately 85 degrees each and are defined by radii lines indicated at 33 and 34, respectively, the center points 33a and 34a of which lie on opposite sides of longitudinal axis 22 generally on minor axis 25. This arrangement provides for the flattened head configuration due to the extremely large radius of center arcuate section 30, whose radius 31 preferably is about three times greater than that of outer arcuate section radii 33 and 34. In the preferred embodiment, radius 31 is approximately 12 inches with radii 33 and 34 being approximately 41/2 inches each.

The lower portion of racquet head 2 located between minor axis 25 and frame handles handle ends 7, is symmetrical symmetric and is composed of two symmetrical sections, each of which includes a convexly curved section 35 which is connected to a concavely curved section 36 by a straight section 37. Concave section 36 terminates into parallel handle ends 7. The radii for convex sections 35 are indicated at 38 with their center points 39 being located generally on minor axis 25 on opposite sides of longitudinal center lines 22. The radii for concave sections 36 are indicated at 41 with their center points 42 being located on opposite sides of handle ends 7.

In order to produce an acceptable racquet, a number of parameters had to be considered in developing improved enlarged racquetball racquet 1. The various parameters all work together to produce the desired racquet effect. These various parameters synergistically combined to create a racquet suitable for the market place. These parameters include the weight of the racquet, the center of mass or gravity of the racquet, the stiffness of the frame and the response characteristics. All of these work together to create racquet control. If you change one of the these parameters, it would change the feel of the racquet and affect the way the ball comes off of the string area. Therefore, in developing improved racquet 1, considerably more was involved than merely increasing the size of the strung area to give the player more racquet face and a larger "sweet spot" in which to hit the ball. Unless the various factors were compensated for, the enlarged racquet may have resulted in a completely unsuitable and unsatisfactory racquet for play.

One of these important features is that the center of gravity had to fall within a relatively tight range as described above. This, in combination with the weight of the racquet and the overall length, provides the necessary relationship between these parameters to achieve a satisfactory oversized or enlarged racquet. For example, just making the racquet head larger would increase the weight of the racquet to an unacceptable limit unless the racquethead was sized and configured to provide the desired strength without an increase in weight. Furthermore, the tension of the strings could more easily deform an enlarged racquet head unless the head and frame thereof provided sufficient stiffness to such deformation. Therefore, it was determined that in the preferred size, the length of the racquet is 40 percent greater than its width, although it could fall within the range of between 20 and 60 percent without materially affecting the concept of the invention, although the 40 percent value is believed to provide more satisfactory results.

Minimum frame stiffness is as follows:

(EI)_xx ≧30,000 #in², (EI)_yy ≧7,000 #in², GJ≧700 #in², AE≧0.8×10⁶ #in²

(EI)_xx is the longitudinal bending stiffness. The more stiffness, the less energy is wasted in bending the shaft, and hence it contributes to power. This is shown in FIG. 7.

(EI)_yy is the lateral bending stiffness. It reduces distortion of head geometry at impact, and contributes to power and control by providing an even string response across the racquet face. This is shown in FIG. 8.

(GJ) is the torsional stiffness. It helps eliminate twist and distortion of the frame, and contributes to power and control by providing stability on offcenter hits. It is shown in FIG. 9.

(AE) is axial stiffness or resistance to compression. The more axial stiffness, the less energy dissipated by the head at impact. It contributes to power. It is shown in FIG. 10.

The racquet will be about the same weight as a conventional racquet.

Furthermore, in racquetball the ball is hit in the top one third portion of the string area as opposed to tennis where it is normally hit in the lower two thirds portion of the string area. The particular shape of the enlarged racquet provides a greater amount of strings in the upper one third portion of the racquet head in order to provide a greater string area where the majority of the actual hitting of the ball is accomplished. Also, the enlarged string area and correspondingly the larger "sweet spot" enables the player to hit this desired area more often which will eliminate some of the vibration and stress on the player's arm which occurs when the ball is hit off center or out of the "sweet spot" area.

Another advantage of the improved racquetball racquet is that the center of percussion is moved towards the tip of the racquet more than 11/4 inches as compared to the conventional racquet without affecting the overall weight and balance of the racquet providing a better "sweet spot". The A center of percussion is the a point measured from a reference line or rotation line at which the entire mass of the frame is assumed to act during rotation. With respect to racquets, The the reference line is usually somewhere on the handle, which is described as the functional end of the handle designated END_F in FIGS. 5 and 6. As is well known in the art, the distance from the reference line to the center of percussion may be determined by dividing the moment of inertia by the product of the mass of the racquet and the distance from the reference line to the static center of gravity.

The moment of inertia about the center of percussion depends upon the mass of the racquet and the center of gravity in that mass. Depending upon how that mass is distributed, it has an effect on the static center of gravity and a varying effect on the center of percussion. In comparing FIGS. 5 and 6, one can ascertain that the movement of the sweet spot upwards translates into a spacing from the center of gravity of more than 3.6 inches towards the frame tip. This is derived from the fact that in conventional racquetball racquets, the center of percussion is located approximately 13.9 inches from the butt end of the handle (FIG. 5). In the racquet of the instant invention (FIG. 6), the center of gravity is located at a distance 10.3 inches from the butt end of the handle. Thus, assuming no upward movement of the center of percussion, the center of percussion of the novel racquet (FIG. 6) would be located at a distance of 3.6 inches from the center of gravity (13.9-10.3). Since the center of percussion has been moved upwards though, its location can be described as being spaced from the center of gravity by a distance greater than 3.6 inches.

The percentage of the string area above and below a line drawn transversely through the midpoint of the central longitudinal string(s), thus showing the larger string area in the normal hitting area of the oversized racquetball racquet versus the smaller string area towards the throat piece or the handle, is shown in the table below.

______________________________________
Area Above/Below
Mid Point
of Center Mainstrings
in2
Percent
______________________________________
Oversized Racquet
57.5/34.0
62.9/37.1
Conventional Racquet
32.1/27.7
53.7/46.3
______________________________________

While in accordance with the patent statutes, only the best mode and preferred embodiment of the invention has been illustrated and described in detail, it is to be understood that for the true scope and breadth of the invention, reference should be had to the appended claims.

Claims

1. A racquetball racquet comprising a frame having a head connected to a handle grip so as to have an overall length of 19 to 221/2 inches and a weight of 220 grams to 270 grams, said head having a strung surface of 75 to 100 square inches, the length of said strung surface in a direction along the longitudinal axis of the racquet being between 12 and 143/4 inches and between 53 and 68 percent of the length of the racquet, said frame and said strung surface having a maximum width between 91/2 and 111/2 inches in a direction generally perpendicular to said longitudinal axis, the center of gravity of the racquet being at a location within a range of 3/4 inch toward the handle grip and 1/2 inch toward the head as measured from the longitudinal center point of the racquet, and the center of percussion average is spaced from the center of gravity toward the head a distance substantially greater than 3.6 inches.

2. The racquetball racquet defined in claim 1 in which the head has a generally oblong shape with a slightly flattened outer end; and in which major and minor axes intersect at a location on the longitudinal center line of the racquet spaced above the center point of the strung area.

3. The racquetball racquet defined in claim 2 in which the lower portion of the head frame between the minor axis and handle grip is defined by two symmetrical curved sections which join at their lower ends at the handle grip; and in which each of the curved sections include an upper outwardly convex curved section and lower inwardly concave curved section.

4. The racquetball racquet defined in claim 3 in which a head frame includes a straight section located between the convex and concave sections of each of the lower portions of the head frame.

5. The racquetball racquet defined in claim 2 in which the lower portion of the strung surface is defined by a concavely shaped throat.

6. A racquetball racquet as defined in claim 2 in which the minor axis as measured across the widest portion of the frame defines a chord which subtends an arc, said arc defining an upper portion of the head and being comprised of three arcuate sections having three separate center points.

7. A racquetball racquet defined in claim 6 in which a center arcuate section of said three arcuate sections has a radius that is approximately three times longer than the length of each of the radii of the other two arcuate sections which are equal to each other.

8. The racquetball racquet defined in claim 7 in which the arcuate length of the center arcuate section is approximately 10 degrees and the arcuate length of each of the other two arcuate sections is approximately 85 degrees.

9. The racquetball racquet defined in claim 8 in which the center points of said other two arcuate sections lie generally on the minor axis, each located on an opposite side of the longitudinal center line of the racquet.

10. The racquetball racquet defined in claim 1 in which the racquet has an overall length of 201/2 inches, a strung area of 85 to 95 square inches, and a weight of 240 to 250 grams.

11. A racquetball racquet as defined in claim 1 in which the center of gravity is at a location within a range of 1/4 inch toward the handle grip and 1/2 inch toward the head of the racquet as measured from the longitudinal center point of the racquet.

12. The racquetball racquet defined in claim 1 in which the strung surface is strung with strings at a tension of between 30 and 45 pounds.

13. The racquetball racquet defined in claim 1 in which said handle grip has a free end and wherein the center of percussion average is located about 151/4 inches from the free end of the handle grip.

14. The racquetball racquet defined in claim 1 in which the length of the strung surface is within the range of 20 and to 60 percent greater than the width of the strung area.

15. A racquetball racquet as defined in claim 1 where the longitudinal moment of inertia is between 50 to 90 g. in. sec².

16. The racquetball racquet as defined in claim 1 where minimum frame stiffness is defined as follows:

(EI)_xx ≧30000#in.², (EI)_yy ≧7000#in.², (GJ) 700#in.², (AE)≧0.8×10⁶ #in.² where (EI)_xx is the longitudinal bending stiffness, (EI)_yy is the lateral bending stiffness, (GJ) is the torsional stiffness and (AE) is axial stiffness.

17. A racquetball racquet as defined in claim 1 therefor: wherein said head has a top portion located opposite the point where said head and handle grip are connected and wherein about 62.9 percent of said strung surface is located on the top portion side of a line located transversely through the midpoint of at least one central longitudinal string.