The present invention relates to a machine for stringing racquets. This stringing machine has enhanced ergonomic features.
The act of stringing a racquet requires a considerable amount of manual labor. Stringing machines assist in the process by maintaining the racquet in place and providing desired tension in the strings, but a majority of the work involved is performed by a person. More particularly, a person must align the racquet within the stringing machine, and then string each of the cross or main strings individually, followed by weaving each of the cross and main strings to form the resulting string grid.
Those in the racquet stringing business often spend many hours a day standing in front of a stringing machine. Conventional stringing machines include a stringing platform with a turntable positioned on top of a fixed stand. The turntable spins within a plane parallel to the floor. Because of the fixed orientation of the stand and the planar position of the turntable, the person stringing the racquet must adjust his or her posture to conform to the position of the stringing machine. In particular, one of the racquet stringer's shoulders is often positioned much higher than the other. Also, the fixed orientation of the stringing machine often induces the racquet stringer to hunch over the turntable. The awkward posture induced by conventional stringing machines often causes injuries and fatigue, which ultimately lead to reduced efficiency in the performance of the racquet stringer. Additionally, conventional stringing machines typically include a vertical stand on a base. The stand and/or base can interfere with the placement of the stringer's feet and/or legs, leading to additional awkwardness in the stringer's posture.
During the stringing process, the racquet is clamped to the stringing platform and the turntable allows the racquet stringer to manually spin the racquet to adjust the positioning of the racquet with respect to the various steps of the stringing process. Turntables on conventional stringing machines are generally free to spin in response to any applied tangential force unless or until a brake is applied, with the brake preventing any further spinning. If the stringing platform were positioned in the stringing machine such that the turntable spins in a plane non-parallel with the floor, namely tilted toward the racquet stringer, the handle of any racquet clamped to the stringing platform would be drawn by gravity to the lowest point within the plane. Consequently, even though the positioning of the turntable may be more comfortable for the user, the need to either continually move the racquet back into its intended position or continually lock and unlock the brake on the turntable in order to overcome the effects of gravity on the clamped-on racquet would be a nuisance.
It would thus be desirable to provide a stringing machine that is ergonomically designed to allow users to work with the stringing machine without having to assume awkward or uncomfortable positions, and without having to continuously manually override effects of gravity on the turntable.
The present invention presents an ergonomically-designed racquet stringing machine for stringing of a racquet by a user. The stringing machine includes a base configured for supporting the stringing machine on a generally horizontal surface, a stand having upper and lower end regions, the lower end region of the stand upwardly extending from a first location of the base, an adjustable stringing platform coupled at a second location to the upper end region of the stand, and a string tensioning assembly coupled to the stand.
The “first location” of the base may be defined as the center of the footprint resulting from the attachment of the stand to the base. Similarly, the “second location” may be defined as the center of the footprint resulting from the attachment of the stringing platform to the stand. The “footprint” is a two-dimensional representation of the intersection of two parts that depicts the area of that intersection. The first and second locations define a line that is angled by a predetermined angle from horizontal.
In one embodiment, the stand extends from the base at an angle between about 70 and about 89 degrees from a horizontal plane (1 and 20 degrees from a vertical plane). Alternatively, the angle between the stand and the base may be between about 80 and about 85 degrees from a horizontal plane (5 and 10 degrees from a vertical plane), for example 83 degrees from a horizontal plane (7 degrees from a vertical plane). This angled orientation of the stand provides ample legroom for the user standing in front of the stringing machine. Additionally, a forward side of the base intended to face the user may define a recessed area for accommodating at least a portion of the user's feet thereby enabling the user to stand closer to the racquet during stringing.
The angle between the base and the stand may be adjustable. For instance, a stand adjustment assembly capable of adjusting the angle of the line defined by the first and second locations may be coupled to the base and the stand. The stand adjustment assembly may be configured to adjust the angle of the line within a range of 0.1 to 15.0 degrees.
In another embodiment, the adjustable stringing platform may include a turntable rotatable about a first axis, and a first releasable resistance assembly, such as a grease brake, coupled to the turntable. The first releasable resistance assembly may be positionable between an engaged operating position in which the resistance assembly resists rotation of the turntable about the first axis, and a disengaged operating position in which the resistance assembly does not resist rotation of the turntable about the first axis.
The first releasable resistance assembly can provide resistance to unintentional rotation of the turntable. In particular, the first releasable resistance assembly can negate the effects of gravity when a racquet is in place and the stringing platform is tilted, such as may be caused by the tilted angle of the stand. For example, the first releasable resistance assembly may provide a resistance against rotation of the turntable (resistance against a torque) about the first axis of within the range of 0.1 to 36 in-lbf, or more preferably within the range of 0.1 to 12.0 in-lbf.
The first releasable resistance assembly suitably includes a high viscosity fluid, such as a grease, for resisting rotation of the turntable when in the engaged operating position. The high viscosity fluid may have a viscosity range of 1 to 500 centipoise (cP), for example. In certain embodiments, the first releasable resistance assembly includes first and second members contacting the high viscosity fluid, with at least one of the first and second members being rotatable about the first axis. The first and/or second members may include a plurality of projections, such as spaced-apart concentric rings, contacting the fluid. For example, each of the first and second members may include a plurality of spaced-apart concentric rings with the rings of the first and second portions configured to correspond to each other such that portions of the rings of one of the members fit within the spaces between the rings of the other member. The first releasable resistance assembly may also include a latch that releasably engages the first member to prevent the first member from rotating about the first axis.
A second releasable resistance assembly, separate from the first releasable resistance assembly, may also be coupled to the stringing platform. For example, the turntable may include a ring centered about the first axis, and the second releasable resistance assembly may be configured to releasably engage the ring to prevent rotation of the turntable about the first axis.
Any one or more of the stringing machine embodiments described herein may be applied to machines for stringing tennis racquets, racquetball racquets, squash racquets, badminton racquets, and any other strung racquet. Regardless of the type of racquet, compatibility of the stringing machine with the user is greatly improved by using any of the stringing machine enhancements in this invention.
Referring to
The stringing machine 20 includes a base 22 configured for supporting the stringing machine 20 on a generally horizontal surface, and a stand 24 having an upper end region 28 and a lower end region 30. The lower end region 30 of the stand 24 extends upwardly from a first location 32 on the base 22, and an adjustable stringing platform 26 is coupled to the upper end region 28 of the stand 24 at a second location 34 on the stringing platform 26, as shown in
The “first location” 32 on the base 22 may be defined as the center of the footprint 36 resulting from the attachment of the stand 24 to the base 22. Similarly, the “second location” 34 may be defined as the center of the footprint 38 resulting from the attachment of the stringing platform 26 to the stand 24. The “footprint” is a two-dimensional representation of the intersection of two parts that depicts the area of that intersection. The first and second locations 32, 34 define a line 40 that is angled by a predetermined angle (θ) from horizontal. It is this line 40 to which we refer when discussing the angle θ between the stand 24 and the base 22. The stand 24 itself may be curved, such as a “C” shape, or may appear to be bent at one or more locations along its length, but in any case, if the line 40 connecting the first location 32 and the second location 34 defines an angle θ from horizontal within the range defined herein, the stringing machine 20 is still considered to fall within the scope of this invention.
In certain embodiments, the stand 24 extends from the base 22 at an angle θ between about 70 and about 89 degrees from a horizontal plane (1 and 20 degrees from a vertical plane), in a direction generally toward the user. Alternatively, the angle θ between the stand 24 and the base 22 may be between about 80 and about 85 degrees from a horizontal plane (5 and 10 degrees from a vertical plane), for example 83 degrees from a horizontal plane (7 degrees from a vertical plane). In contrast, conventional stringing machines are configured with a stand that extends perpendicularly from a base. The angled orientation of the stand 24 described in the present invention provides ample legroom for the user standing in front of the stringing machine 20. More particularly, by tilting the stand 24 at an angle θ non-perpendicular to the base 22, more legroom can be created for the user, thereby allowing the user to stand closer to the stringing machine 20. For example, a 7-degree tilt, such that the angle θ is 83 degrees from a horizontal plane, provides 40-50% more legroom compared to a stand 24 that is perpendicular to the base 22.
Additionally, the base 22 may be configured to provide a comfortable standing area for the user. The base 22 includes a forward side 42 intended to face the user and a rear side 44 opposite the forward side 42. As illustrated in
When stringing a racquet, the racquet must first be clamped onto the adjustable stringing platform 26. As illustrated in
Additional steps in the stringing process also induce poor posture for many users. As shown in
Similarly, the detail-oriented process of weaving cross strings may also cause neck strain or other discomfort, as exemplified in
The base 22 and stand 24 may be a single-leg design, as illustrated in
In certain embodiments, the angle θ between the base 22 and the stand 24 may be permanently fixed, or non-adjustable. In other embodiments, however, the angle θ between the base 22 and the stand 24 may be adjustable. For instance, a stand adjustment assembly capable of adjusting the angle θ of the line 40 defined by the first and second locations 32, 34 may be coupled to the base 22 and the stand 24. The stand adjustment assembly may be configured to adjust the angle θ of the line 40 within a range of 0.1 to 15.0 degrees.
The angular adjustment between the base 22 and the stand 24 may be performed either manually or automatically. For example, the stand adjustment assembly may include a drive mechanism formed by a chain that runs in a track. The drive mechanism may be controlled electronically, for example. Those skilled in the art are familiar with a variety of suitable drive mechanisms that would be appropriate for adjusting the angle θ between the base 22 and the stand 24. Therefore, the details of such mechanisms will not be described in detail herein.
As illustrated in
In certain embodiments, the stringing platform 26 may include a turntable 54 rotatable about a first axis 56, and a first releasable resistance assembly 58, such as a grease brake, coupled to the turntable 54, as shown in
The first releasable resistance assembly 58 can provide resistance to unintentional rotation of the turntable 54. In particular, the first releasable resistance assembly 58 can negate the effects of gravity when a racquet is in place and the stringing platform 26 is tilted, such as may be caused by the tilted angle of the stand 24. For example, the first releasable resistance assembly may provide a resistance against rotation of the turntable (resistance against a torque) about the first axis of within the range of 0.1 to 36 in-lbf, or more preferably within the range of 0.1 to 12.0 in-lbf.
The first releasable resistance assembly 58 suitably includes a high viscosity fluid, such as a grease, for resisting rotation of the turntable 54 when in the engaged operating position. The high viscosity fluid may have a viscosity range of 1 to 500 cP, for example. By using such a highly viscous lubricant, the turntable 54 can be maintained in place, even when the turntable 54 is lying in a plane non-parallel to the horizontal surface on which the stringing machine 20 is standing, without the need to mechanically lock the turntable 54 in place.
In certain embodiments, the first releasable resistance assembly 58 includes first and second members 60, 62 contacting the high viscosity fluid, with at least one of the first and second members 60, 62 being rotatable about the first axis 56.
The first releasable resistance assembly 58 may also include a latch 64 that releasably engages the first member 60 to prevent the first member 60 from rotating about the first axis 56. The latch 64 may be manually operated or remotely operated through a conventional actuation mechanism. In one preferred embodiment, the latch 64 can be used to switch the first resistance assembly 58 between the engaged operating position in which the resistance assembly 58 resists rotation of the turntable 54 about the first axis 56, and a disengaged operating position in which the resistance assembly 58 does not resist rotation of the turntable 54 about the first axis 56. When the latch 64 is positioned to engage the first member 60 and to prevent the member 60 from rotating about the first axis 56, the second member 62 remains free to rotate about the first axis 56. However, with the first member 60 in a locked position, the second member 62 rotates with respect to the first member 60 and the high viscosity fluid positioned between the corresponding projections of the first and second members 60 and 62 provides resistance to rotation of the second member 62 about the first axis 56.
As illustrated in
Any one or more of the stringing machine embodiments described herein may be applied to machines for stringing tennis racquets, racquetball racquets, squash racquets, badminton racquets, and any other strung racquet. In particular, the stringing machine 20 may be used to string racquets for use in an organized professional league and/or in competitive play. Furthermore, the stringing machine 20 may be configured to string racquets in a manner that meets ITF Rules of Tennis requirements for racquet strings. Regardless of the type of racquet, compatibility of the stringing machine 20 with the user is greatly improved by using any of the stringing machine enhancements in this invention.
While the preferred embodiments of the invention have been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention. For example, while the embodiments described herein are illustrated in a stringing machine for stringing a tennis racquet, the principles of the present invention could also be used for stringing machines for stringing practically any other type of racquet. Accordingly, it will be intended to include all such alternatives, modifications and variations set forth within the spirit and scope of the appended claims.
Provisional Application Ser. No. 60/922,799 filed on Apr. 11, 2007
Number | Date | Country | |
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60922799 | Apr 2007 | US |