U.S. patent number RE33,372 [Application Number 07/398,263] was granted by the patent office on 1990-10-09 for tennis racket.
Invention is credited to Jack L. Frolow.
United States Patent |
RE33,372 |
Frolow |
October 9, 1990 |
Tennis racket
Abstract
A tennis racket having an unconventional weight and stiffness
distribution providing for the same swing weight as rackets of the
prior art, a large distance of the center of percussion from the
handle end, and a weight means in the grip portion of the racket
for reducing the shock and vibration transmitted to the player's
arm, when the player impacts the ball with the racket.
Inventors: |
Frolow; Jack L. (Long Branch,
NJ) |
Family
ID: |
23574692 |
Appl.
No.: |
07/398,263 |
Filed: |
August 24, 1989 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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Reissue of: |
543431 |
Oct 19, 1983 |
04690405 |
Sep 1, 1987 |
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Current U.S.
Class: |
473/523 |
Current CPC
Class: |
A63B
49/022 (20151001); A63B 49/08 (20130101); A63B
49/028 (20151001); A63B 60/54 (20151001); A63B
49/02 (20130101); A63B 60/16 (20151001); A63B
60/002 (20200801); A63B 2049/0207 (20151001); A63B
2049/0212 (20151001); A63B 60/24 (20151001) |
Current International
Class: |
A63B
49/02 (20060101); A63B 49/00 (20060101); A63B
59/00 (20060101); A63B 53/14 (20060101); A63B
049/04 () |
Field of
Search: |
;273/73C,73D,73R,73F,73H,73E,73J,73R,73L,75,67A,DIG.7,DIG.23 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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848826 |
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Aug 1970 |
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CA |
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2721715 |
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Dec 1977 |
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DE |
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2496471 |
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Jun 1982 |
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FR |
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645381 |
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Sep 1962 |
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IT |
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8112 |
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1884 |
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GB |
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Other References
"Close Encounters with Space Age Fibers", Tennis Magazine, Jun.
1983, pp. 41-43..
|
Primary Examiner: Coven; Edward M.
Assistant Examiner: Stoll; William E.
Claims
I claim:
1. A complete tennis racket held by the hand of a player to impact
a ball comprising at least a frame including a head portion
supporting a string netting in a plane and a handle portion having
a grip portion suitably adapted for the hand to grip, the end of
the grip portion being located at the handle portion end of the
racket, said racket having a longitudinal axis running from the
center of the head portion end of the racket to the center of the
grip portion end of the racket; said racket having a weight and
stiffness distribution providing for a frequency of vibration
f.sub.1, in cycles per second when tested in accordance with test
13 of FIG. 15 herein before defined; said racket having a weight
distribution providing for a center of percussion located at a
distance Cp in inches from the end of the grip portion when tested
in accordance with test 4 of FIG. 15 herein before defined, said
center of percussion taken about a pivot located at the end of the
grip portion, said pivot having an axis perpendicular to the
longitudinal axis of said frame and parallel to the plane of said
string netting; said racket characterized in that said handle
portion has a system comprising a weight means and a means for the
attachment of said weight means to the handle portion of the racket
for reducing the shock and vibration received by the player's hand
during the impact of the racket with the ball and the vibration
subsequent to said impact; said system having a center of gravity
being located at all times at a distance F from the end of the grip
portion, said distance F being less than 0.26 of the overall length
of said racket along said longitudinal axis; said weight means
being firmly attached to said handle portion to provide that
responsive to a single impulsive force to said weight means there
is no significant movement between said weight means and said
handle portion; and said racket excluding said system has said
distance Cp greater than 18.75 inches; and said racket excluding
said system has said frequency of vibration f.sub.1 greater than
140 cycles per second; said racket having a weight distribution
provided for a moment of inertia Ia in ounce-inches squared about
said longitudinal axis and the magnitude of Ia is greater than 75
ounce-inches squared, and the said magnitude of Ia being attained
without a weight means being attached to the said head portion of
the racket.
2. A tennis racket as in claim 1 wherein said handle portion
resists mechanical forces, said forces resulting from said impact
of the racket with the ball, said handle portion comprises a thin
wall tube substantially only one material and said material
resisting substantially all of said mechanical forces resisted by
said handle portion, said one material being a composite of fibers
and resin.
3. A racket as in claim 1 wherein aid racket including said system
has a weight W in ounces; and said racket including said system has
a center of gravity located at a distance Cg in inches from said
end of the grip portion; said racket characterized in that the
product of said distance Cg and said weight W given by the formula
WCg is less than 160 ounce inches.
4. A complete tennis racket held by the hand of a player to impact
a ball comprising at least a frame having a head portion supporting
a string netting in a plane and a handle portion being a hollow
tube said tube having a side wall said handle portion having a grip
portion suitably adapted for the hand to grip, the end of the grip
portion being located at the handle portion end of the racket; said
racket having a longitudinal axis running from the center of said
head portion end of the racket to the center of said grip portion
end of the racket; said netting having a length along the
longitudinal axis of said frame greater than 9 inches and a width
along an axis perpendicular to said axis greater than 7.5 inches;
said racket having a weight distribution providing a center of
percussion located at a distance Cp in inches from the end of the
grip portion when tested in accordance with test 4 of FIG. 15
herein before defined, said center of percussion taken about a
pivot located at the end of the grip portion, said pivot having an
axis perpendicular to the longitudinal axis of said racket and
parallel to the plane of said string netting; said racket having a
weight and stiffness distribution providing a frequency of
vibration f.sub.1 in cycles per second when tested in accordance
with test 13 of FIG. 15 herein before defined, said racket
characterized in that said handle portion has a system comprising a
weight means and a means for the attachment of said weight means to
the handle portion of the racket for reducing the shock and
vibration received by the player's hand during the said impact of
the racket with the ball and the vibration subsequent to said
impact; said system having a center of gravity being located at all
times between the end of the grip portion and points located on the
handle portion at a distance F from the end of the grip portion,
said distance F being equal to 0.26 of the overall length of said
racket along said longitudinal axis; said weight means being
loosely attached to said handle portion; substantial space being
provided between said weight means and said side wall of said
handle portion, said space allowing said weight means to attain
significant velocity with respect to said handle portion in the
direction perpendicular to said longitudinal axis upon impact of
said racket with said ball, the plane of said netting being
substantially parallel to the direction of the force of gravity
upon impact of said racket with said ball; said weight means being
capable of absorbing energy from the racket handle portion said
energy being induced in said handle portion when the racket impacts
the ball; said weight means and said means for the attachment of
said weight means to the handle portion of the racket being
configured and structured to provide that responsive to a single
impulsive force to said weight means the movement between said
weight means and said handle portion is not vibratory at a
frequency f.sub.2, said frequency f.sub.2 being greater than 0.45
of said frequency f.sub.1 and being less than 1.55 of said
frequency f.sub.1 ; and said racket including said system having a
weight W in ounces, and said racket including said system having a
center of gravity located at a distance Cg in inches from the end
of said grip portion; said racket having the product of said weight
W and said distance Cg given by the formula WCg being less than 160
ounce-inches and said racket including said system having said
distance Cp greater than 18.75 inches; and said racket excluding
said system having a frequency f.sub.1 greater than 115 cycles per
second.
5. A tennis racket as in claim 4, and said racket including said
system having a weight less than 10.7 ounces.
6. A tennis racket as in claim 4; and said weight W is greater than
10.7 ounces.
7. A tennis racket as in claim 4 wherein said weight means
comprises a strip of material, said strip not being a liquid.
8. A tennis racket as in claim 7 wherein said strip of material
comprises an enclosure containing material capable of absorbing
energy.
9. A tennis racket as in claim 4, wherein the said movement between
said weight means and the said handle portion does not vibrate
between two extreme positions from said handle portion a plurality
of cycles.
10. A complete tennis racket held by the hand of a player for
impacting a ball comprising at least a frame having a head portion
and a throat portion supporting a string netting in a plane, and a
handle portion having a grip portion suitably adapted for the hand
to grip, the end of the grip portion being located at the handle
portion end of the racket; said racket having a longitudinal axis
running from the center of the head portion end of the racket to
the center of the grip portion end of the racket; said netting
having a length along the longitudinal axis of said frame greater
than 9 inches and a width along an axis perpendicular to said axis
greater than 7.5 inches; a center of percussion located at a
distance Cp in inches from the end of the grip portion when tested
in accordance with test 4 of FIG. 15 herein before defined, said
center of percussion taken about a pivot located at the end of the
grip portion said pivot having an axis perpendicular to the
longitudinal axis of said racket and parallel to the plane of said
netting; said racket having a center of gravity located at a
distance Cg in inches from the end of the grip portion; said racket
having a weight distribution providing a moment of inertia Ia in
ounce inches squared about said longitudinal axis; said racket
having a weight W in ounces; said racket chracterized in that the
product of said distance Cg and said weight W given by the formula
WCg is less than 160 ounce-inches; and said distance Cp is greater
than 18.75 inches; and said weight is greater than 10.7 ounces; and
the magnitude of Ia is greater than 80 ounce-inches squared.
11. A tennis racket as in claim 10 wherein said netting has a
length along said longitudinal axis greater than 12 inches.
12. A tennis racket as in claim 11 wherein said head portion is
substantially only one material being a formed aluminum tube having
a crossectional shape, said shape having a wall thickness less than
0.044 inches and a perimeter of the outer surface being greater
than 2.125 inches; said tube having a single cavity along its
length.
13. A tennis racket as in claim 10 and said head portion comprising
a crown portion and two adjacent side portions, said side portions
extending from the end of said handle portion to joint the said
crown portion; said crown portion comprising a metal tube having a
thin wall, said side portions being a thin wall tube comprising
substantially only one material and said material being a composite
material of fibers and resin.
14. A tennis racket as in claim 10 wherein said netting has
vertical strings and horizontal strings entering string holes
located in said frame; means for spacing at least two of said
vertical strings at locations in the vicinity of said throat
portion of the racket to provide that at least two of said string
holes are displaced to the side away from said longitudinal axis;
said means comprising a member capable of retaining said vertical
strings in spaced paths as said strings pass through said member,
said member in conjunction with said string holes located in said
frame deflecting each of said vertical strings to the side forming
at least two portions said portions forming an angle of at least 15
degrees; said member being supported by said strings; said member
being capable of moving together with said strings freely with
respect to said frame.
15. A tennis racket as in claim 14 wherein said member has a weight
less than 1 ounce.
16. A racket as in claim 10 wherein said moment of inertia Ia is
greater than 95 oz-inches squared.
17. A racket as in claim 10 wherein said racket has an overall
length along said longitudinal axis less than 27.75 inches.
18. A tennis racket having a frame having a head portion, a throat
portion, and a handle portion, said head portion and said throat
portion of said frame supporting a string netting in a plane, said
netting having vertical strings and horizontal strings, said
strings entering string holes located in said frame; said racket
having a longitudinal axis running from the center of the head
portion end of the racket to the center of the handle portion end
of the racket; means for providing that the vertical strings in the
vicinity of said longitudinal axis terminate at string holes in the
throat portion of the racket being located at a greater distance
from the junction of said throat portion and the said handle
portion than the distance that occurs when the said vertical
strings in the vicinity of said longitudinal axis proceed between
said string holes in a single straight line, said line being
parallel to said longitudinal axis; means comprising a first member
for spacing at least two of said vertical strings at locations in
the vicinity of said throat portion of the racket; said first
member capable of retaining said vertical strings in spaced paths
as said strings pass through said first member; said first member
in conjunction with said string holes located in said frame
deflecting each of said vertical strings to the side thereby
forming at least two portions forming an angle of at least 15
degrees; said first member being supported by said strings; said
first member being capable of moving together with said strings
freely with respect to said frame.
19. A tennis racket as in claim 18, wherein said member has a
weight less than 1 ounce.
20. A complete tennis racket having at least a head portion and a
handle portion, said handle having a grip portion suitably adapted
for the hand to grip, the end of the grip portion being located at
the handle portion end of the racket; said head portion supporting
a string netting in a plane, said netting having vertical and
horizontal strings; said racket characterized in that the longest
vertical string has a length greater than 12 inches and the longest
horizontal string has a length greater than 9.5 inches; and said
racket having a weight W in ounces, and the said W being less than
10.7 ounces; said racket having a weight distribution providing for
the center of percussion located at a distance Cp in inches from
the end of the grip portion when tested in accordance with test 4
of FIG. 15 herein before defined, said center of percussion taken
about a pivot located at the end of the grip portion, a
longitudinal axis running from the center of the grip portion end
of the racket to the center of the head portion end of the racket,
said pivot having an axis perpendicular to said longitudinal axis,
and being parallel to the plane of said string netting; said
distance Cp being greater than 18.75 inches; and said racket having
a weight distribution providing for the center of gravity of said
racket being located at a distance CG in inches from said end of
the grip portion; said racket having a weight distribution
providing for the moment of inertia Ia in ounce-inches squared
about said longitudinal axis; said racket further characterized in
that the product of said distance Cg and said weight W given by the
formula WCg is less than 160 ounce-inches; and the magnitude of Ia
is greater than 80 ounce-inches squared and the said magnitude of
Ia being attained without a weight means being attached to the said
head portion of the racket.
21. A racket as in claim 20 wherein said racket having an overall
length L along said longitudinal axis; and said distance Cp divided
by said distance L given by the formula Cp/L being greater than
0.70.
22. A racket as in claim 20 wherein said head portion comprises a
frame being a hollow tube having a length, said tube having a
single cavity along its length, said tube having a crossectional
shape, said shape having a wall thickness less than 0.044 inches
and the perimeter of the outside surface being greater than 2.125
inches, said tube being devoid of a seam having overlapping
surfaces said seam being in the direction of the length of said
tube.
23. A racket as in claim 22 wherein said head portion is shaped to
support said string netting, said netting exerting mechanical
forces on said head portion, said head portion having a crown
portion and two adjacent side portions converging toward and
joining said handle portion, said side portions forming a throat
portion adjacent to said handle portion, said throat portion being
devoid of a throat member said member being located between said
side portions and said member providing structural support
resisting significantly said mechanical forces exerted by said
netting on said head portion.
24. A racket held by the hand of a player to impact a ball
comprising at least a frame having a head portion supporting a
netting in a plane; said handle portion having a hollow tube said
tube having a side wall, said handle portion having a grip portion
suitably adapted for the hand to grip, the end of the grip portion
being located at the handle portion end of the racket; said racket
having a longitudinal axis running from the center of the head
portion end of the racket to the center of the handle portion end
of the racket; and said racket having a system comprising a weight
means and a means for the attachment of said weight means to the
handle portion of said racket providing for the reduction of the
shock and vibration received by the player's hand during the said
impact of the racket with the ball and the vibration subsequent to
the said impact; said weight means comprising a strip of material
suitable to absorb shock and vibration energy from said racket
handle portion, said energy being induced in said handle portion
when the racket impacts the ball; said strip of material not being
a liquid; said weight means having a center of gravity being
located at all times between the end of the grip portion and points
located on the handle portion at a distance F from the end of the
grip portion, said distance F being less than 0.26 of the overall
length of said racket along said longitudinal axis; said weight
means being loosely attached to said handle portion, substantial
space being provided between said weight means and the said side
wall of said handle portion, said space allowing said weight means
to attain significant velocity with respect to the handle portion
in a direction perpendicular to said longitudinal axis upon impact
of said racket with said ball, the plane of said string netting
being substantially parallel to the direction of the force of
gravity upon said impact of the racket with said ball; said racket
exclusive of said system having a weight and stiffness distribution
providing a frequency of vibration f.sub.1 in cycles per second
when tested in accordance with test 13 of FIG. 15 herein before
defined; said weight means and said means for the attachment of
said weight means being configured and structured to provide that
responsive to a single impulsive force to said weight means, the
movement between said weight means and said handle portion is not
vibratory at a frequency f.sub.2, and said frequency f.sub.2 being
greater than 0.45 of said frequency f.sub.1 and being less than
1.55 of said frequency f.sub.1.
25. A racket as in claim 24 wherein said strip of material is an
enclosure containing a material suitable to absorb energy.
26. A racket as in claim 24 wherein said strip of material is
capable of impacting the racket handle when the racket impacts the
ball; and said strip having a length along the longitudinal axis of
aid racket, less than 7.0 inches.
27. A racket as in claim 24, wherein said distance F is less than
0.175 of the overall length of said racket along said longitudinal
axis.
28. A tennis racket as in claim 24 wherein the said movement
between said weight means and the said handle portion does to
vibrate between two extreme positions from said handle portion a
plurality of cycles.
29. A complete tennis racket held by the hand of a player to impact
a ball comprising at least a frame having a head portion and a
handle portion, said head portion supporting a string netting in a
plane and said handle portion having a grip portion suitably
adapted for the hand to grip, the end of the grip portion being
located at the handle portion end of the racket, said racket having
a longitudinal axis running from the center of the head portion end
of the racket to the center of the grip portion end of the racket,
said netting having a length along the longitudinal axis of said
frame greater than 9 inches and a width along an axis perpendicular
to said longitudinal axis greater than 7.5 inches; said racket
having a center of percussion located at a distance Cp in inches
from the end of the grip portion when tested in accordance with
test 4 of FIG. 15 herein before defined said center of percussion
taken about a pivot located at the end of the grip portion, said
pivot having an axis perpendicular to the longitudinal axis of said
racket and parallel to the plane of said string netting; said
racket characterized in that said racket has a system comprising a
weight means and a means for the attachment of said weight means to
the handle portion of the racket for the reduction of the shock and
vibration received by the player's hand during the said impact of
the racket with the ball and the vibration subsequent to the said
impact; said racket exclusive of said system having a weight less
than 10.7 ounces; said racket exclusive of said system having said
distance Cp greater than 18.75 inches; said racket exclusive of
said system having a weight and stiffness distribution providing a
frequency of vibration f.sub.1 in cycles per second when tested in
accordance with test 13 of FIG. 15 herein before defined; said
weight means comprising at least one member, said weight means
being located in the handle portion of the racket said weight means
having a weight greater than 0.75 ounces, said weight means having
a center of gravity being located at all times in the portion of
the racket located between the end of the grip portion and set of
points located on the handle portion at a distance F from the end
of the grip portion; said distance F being less than 0.175 of the
overall length of the racket along said longitudinal axis; said
weight means and said means for the attachment of said weight means
being configured and structured to provide that responsive to a
single impulsive force to said weight means, the movement between
said weight means and said handle portion is not vibratory at a
frequency f.sub.2, and said frequency f.sub.2 being greater than
0.45 of said frequency f.sub.1 and being less than 1.55 of said
frequency f.sub.1.
30. A racket as in claim 29 wherein said weight means has a weight
greater than 1.0 ounce.
31. A racket as in claim 29 wherein said weight means is loosely
attached to said handle portion; substantial space being provided
between said weight means and the said handle portion, said space
allowing said weight means to attain significant velocity with
respect to said handle portion in the direction perpendicular to
said longitudinal axis of the racket upon impact of said racket
with said ball, the plane of said string netting being
substantially parallel to the direction of the force of gravity
upon impact of said racket with said ball.
32. A complete tennis racket held by the hand of a player to impact
a ball comprising at least a frame having a head portion supporting
a string netting in a plane and a handle portion being a hollow
tube, said tube having a side wall, said handle portion having a
grip portion suitably adapted for the hand to grip, the end of the
grip portion being located at the handle portion end of the racket,
said racket having a longitudinal axis running from the center of
the head portion end of the racket to the center of the grip
portion end of the racket; said netting having a length along the
longitudinal axis of said racket greater than 9 inches and a width
along an axis perpendicular to said axis greater than 7.5 inches;
said racket having a weight distribution providing a center of
percussion located at a distance Cp in inches from the end of the
grip portion when tested in accordance with test 4 of FIG. 15
herein before defined, said center of percussion taken about a
pivot located at the end of the grip portion, said pivot having an
axis perpendicular to the longitudinal axis of said racket and
parallel to the plane of said string netting; said racket
characterized in that said handle portion has a system comprising a
weight means and a means for the attachment of said weight means to
the handle portion of the racket for the reduction of the shock and
vibration received by the player's hand during the impact of the
racket with the ball and the vibration subsequent to said impact;
said weight means being loosely attached to said handle portion;
substantial space being provided between said weight means and said
side wall of said handle portion, said space allowing said weight
means to attain significant velocity with respect to said handle
portion in the direction perpendicular to said longitudinal axis
upon impact of said racket with the said ball, the plane of said
netting being substantially parallel to the direction of the force
of gravity upon impact of said racket with said ball; said weight
means being capable of absorbing energy from the racket handle
portion, said energy being induced in said handle portion when the
racket impacts the ball; said racket exclusive of said system
having a weight and stiffness distribution providing for a
frequency of vibration f.sub.1 in cycles per second when tested in
accordance with test 13 of FIG. 15 herein before defined; said
weight means and said means for the attachment of said weight means
being configured and structured to provide that responsive to a
single impulsive force to said weight means the movement between
said weight means and said handle portion is not vibratory at a
frequency f.sub.2, and said frequency f.sub.2 being greater than
0.45 of said frequency f.sub.1 and being less than 1.55 of said
frequency f.sub.1 ; said weight means having a center of gravity
being located at all times between the end of the grip portion and
points on the handle portion located at a distance F from the end
of the grip portion, said distance F being less than 0.26 of the
overall length of said racket along said longitudinal axis; said
racket excluding said system having a weight less than 10.7 ounces;
said racket excluding said system having said distance Cp greater
than 18.75 inches; and said racket including said system having a
weight greater than 10.7 ounces.
33. A racket as in claim 32, wherein said weight means, and said
means for the attachment of said weight means to the handle portion
of the racket, are configured and structured to provide that
responsive to a single impulsive force to said weight means, the
movement between said weight means and said handle portion does not
vibrate between two extreme positions from said handle portion a
plurality of cycles.
34. A complete tennis racket held by the hand of a player to impact
a ball comprising at least a frame having a head portion supporting
a string netting in a plane and a handle portion, said handle
portion having a grip portion suitably adapted for the hand to
grip, the end of the grip portion being located at the handle
portion end of said racket, said racket having a longitudinal axis
running from the center of the head portion end of the racket to
the center of the grip portion end of the racket, said netting
having a length along the longitudinal axis of said racket greater
than 9 inches and width along an axis perpendicular to said axis
greater than 7.5 inches; said racket having a weight distribution
providing a center of percussion located at a distance Cp in inches
from the end of the grip portion when tested in accordance with
test 4 of FIG. 15 herein before defined said center of percussion
taken about a pivot located at the end of the grip portion, said
pivot having an axis perpendicular to the longitudinal axis of said
racket and parallel to the plane of said string netting; said
racket characterized in that the handle portion has a system
comprising a weight means and a means for the attachment of said
weight means to the handle portion of the racket for reducing the
shock and vibration received by the player's hand during said
impact of the racket with the ball and the vibration subsequent to
said impact; said weight means being firmly attached to said handle
portion to provide that responsive to a single impulsive force to
said weight means, there is no significant movement between said
weight means and said handle portion; said weight means having a
center of gravity being located at all times between the end of the
grip portion and points located on the handle portion at a distance
E from the end of the grip portion, said distance F being less than
0.26 of the overall length of said racket along said longitudinal
axis; said racket excluding said system having a weight less than
10.7 ounces; and said racket excluding said system having a
magnitude of Cp greater than 18.75 inches; and said weight means
having a weight greater than 0.75 ounces; said racket having a
weight distribution providing for a moment of inertia Ia in ounce
inches squared about said longitudinal axis and the magnitude of Ia
is greater than 75 ounce inches squared, and the magnitude of Ia
being attained without a weight means being attached to the said
head portion of the racket.
35. A complete tennis racket held by the hand of a player to impact
a ball comprising at least a frame having a head portion supporting
a string netting in a plane and a handle portion being a hollow
tube having a side wall, said handle portion having a grip portion
being located at the handle portion end of the racket; said racket
having a longitudinal axis running from the center of the head
portion end of the racket to the center of the grip portion end of
the racket; said racket having a weight and stiffness distribution
providing for the nodal pivot closest to the grip portion end of
the racket being located at a distance N in inches from the end of
the grip portion when tested in accordance with test 15 of FIG. 15
herein before defined; said racket having a weight distribution
providing for the center of percussion to be located at distance Cp
in inches from the end of the grip portion when tested in
accordance with test 4 of FIG. 15 herein before defined, said
center of percussion aken about a pivot located at the end of the
grip portion, said pivot having an axis perpendicular to the
longitudinal axis of said racket and parallel to the plane of said
string netting; said racket characterized in that the handle
portion has a system comprising a weight means and a means for the
attachment of said weight means to the handle portion of the racket
for reducing the shock and vibration received by the player's hand
during the said impact of the racket with the ball and the
vibrations subsequent to said impact; said weight means having a
center of gravity being located at all times between the end of the
grip portion and points on the handle portion located at a distance
F from the end of the grip portion, said distance F being less than
0.26 of the overall length of said racket along said longitudinal
axis; said racket exclusive of said system having a weight and
stiffness distribution providing for a frequency of vibration
f.sub.1 when tested in accordance with test 13 of FIG. 15 herein
before defined; said weight means being loosely attached to said
handle portion; substantial space being provided between said
weight means and said sidewall of said handle portion; said space
allowing said weight means to attain significant velocity with
respect to said handle portion in the direction perpendicular to
said longitudinal axis upon impact of said racket with said ball,
the plane of said netting being substantially parallel to the
direction of the force of gravity upon impact of said racket with
said ball; said weight means being capable of absorbing energy from
the handle portion; said energy being induced in said handle
portion when said racket impacts the ball; said weight means and
said means for the attachment of said weight means to the handle
portion of the racket being configured and structured to provide
that responsive to a single impulsive force to said weight means
the movement between said weight means and said handle portion is
not vibratory at a frequency f.sub.2, and said frequency f.sub.2
being greater than 0.45 of said frequency f.sub.1 and being less
than 1.55 of said frequency f.sub.1, and said racket excluding said
system having said nodal distance N being greater than 6.75 inches;
and said racket excluding said system having said distance Cp being
greater than 18.75 inches.
36. A tennis racket as in claim 35 wherein the said movement
between said weight means and said handle portion does not vibrate
between two extreme positions from said handle portion a plurality
of cycles.
37. A complete tennis racket held by the hand of a player to impact
a ball comprising at least a frame having a head portion supporting
a string netting in a plane and a handle portion, said handle
portion having a grip portion being located at the handle portion
end of the racket; said racket having a longitudinal axis running
from the center of the head portion end of the racket to the center
of the grip portion of the racket; said racket having a weight and
stiffness distribution providing for the nodal pivot closest to the
grip portion end being located at a distance N in inches from the
said end of the grip portion when tested in accordance with test 15
herein before described; said racket characterized in that the
handle portion has a system comprising a weight means and a means
for the attachment of said weight means to the handle portion of
the racket, for reducing the shock and vibration received by the
player's hand during said impact of the racket with the ball and
the vibration subsequent to said impact; said weight means having a
center of gravity being located at all times between the end of the
grip portion and points on the handle portion located at a distance
F from the end of the grip portion, said distance F being less than
0.26 of the overall length of said racket along said longitudinal
axis; said weight means being firmly attached to said handle
portion to provide that responsive to a single impulsive force to
said weight means there is no significant movement between said
weight means and said handle portion; said racket exclusive of said
system having a weight distribution providing a center of
percussion being located at a distance Cp from the end of the grip
portion when tested in accordance with test 4 of FIG. 15 herein
before defined said center of percussion taken about a pivot
located at the end of the grip portion, said pivot having an axis
perpendicular to the longitudinal axis of said racket and parallel
to the plane of said string netting and the magnitude of said
distance Cp being greater than 18.75 inches; and said racket
excluding said system having a distance N greater than 6.75 inches;
said racket having a weight distribution providing for a moment of
inertia Ia in ounce-inches squared about said longitudinal axis and
the magnitude of Ia is greater than 75 ounce-inches squared, and
the magnitude of Ia being attained without a weight means being
attached to the said head portion of the racket.
38. A tennis racket used by a player to impact a ball comprising at
least a frame having rigidity and strength with a minimum of weight
in the middle portion of said racket, said frame comprising at
least a head portion and a handle portion; said handle portion
having a grip portion suitably adapted for the hand to grip, the
end of the grip portion being located at the handle portion end of
racket, said racket having a longitudinal axis running from the
center of the head portion end of the racket to the center of the
handle portion end of the racket; said head portion being an
elongated strip of at least two materials having a crown portion
and two adjacent side portions suitably shaped to support a netting
of strings, said strings being stretched and exerting tensile
forces on said head portion, said netting lying in a plane, each of
said side portions extending from said handle portion to join said
crown portion at a first junction; each of said side portions
comprising substantially only a first material, said side portion
resisting mechanical forces, said forces resulting from said
tensile forces exerted by said strings on said head portion, said
first material resisting substantially all of said mechanical
forces resisted by said side portions; said first material being a
composite of fiber reinforced plastic having great strength great
stiffness, and light weight; said crown portion resisting
mechanical forces, said forces resulting from said tensile forces
exerted by the strings on said head portion, said crown portion
comprising a second material, said second material being a major
portion of said crown portion, said second material resisting a
major portion of all said mechanical forces resisted by the crown
portion; said second material not being a composite of fiber
reinforced plastic, said second material having adequate strength
and stiffness.
39. A tennis racket as in claim 38 wherein said handle portion
resists mechanical forces, said forces resulting from the said
impact of the racket with the ball, said handle portion comprising
substantially only one material said material resisting
substantially all of the said forces resisted by said handle
portion said material is a composite material of fibers and resin
said material having light weight and great strength and great
stiffness.
40. A tennis racket as in claim 38 wherein said handle portion is a
thin wall tube having a single cavity said handle portion resisting
mechanical forces said forces resulting from said impact of the
racket with the ball, said handle portion comprising substantially
only one material, said material resisting substantially all of the
said forces resisted by the handle portion said material being
metal; said tube having a crossectional diameter being greater than
1 inch and said side wall being less than 0.030 inches, thereby
providing that said handle portion having adequate stiffness and
strength being light in weight relative to the head portion of said
racket, and having a diameter of said handle portion being
substantially greater than a crossectional diameter of the frame in
the head portion of the racket.
41. A tennis racket as in claim 38 wherein said second material in
the crown portion is a metal strip.
42. A tennis racket as in claim 38 wherein said second material in
the crown portion of said head portion is a wood strip.
43. A tennis racket as in claim 38 wherein said side portions are
thin wall tubes.
44. A tennis racket as in claim 38 wherein said side portions are
hollow thin wall tubes.
45. A tennis racket as in claim 38 wherein said head portion
comprises a crown portion being a member and each of said side
portions being a member, said crown portion member and said side
portion members not being integrally formed to comprise said head
portion, and one end of said crown portion member being fastened to
a first end of each of said side portion members at first junction;
the said handle portion of said racket being fastened to the second
end of each of said side portion members.
46. A tennis racket as in claim 38, wherein said netting has a
length S along said longitudinal axis; and said first junction
being located at a distance J from a transverse axis toward the
head portion end of the racket, said transverse axis being
perpendicular to said longitudinal axis, said transverse axis being
located at the end of said netting along said longitudinal axis
closest to said handle portion of the racket; said distance J being
greater than 0.15 of said distance S. .Iadd.
47. A complete tennis racket having at least a head portion and a
handle portion, said handle portion having a grip portion suitably
adapted for the hand to grip, the end of the grip portion being
located at the handle portion end of the racket; said head portion
supporting a string netting in a plane; said netting having
vertical and horizontal strings; said racket having a longitudinal
axis running from the center of the grip portion end of the racket
to the center of the head portion end of the racket; said racket
having a weight distribution providing for the moment of inertia Ia
in ounce inches squared about said longitudinal axis; said racket
having a weight and stiffness distribution providing a frequency of
vibration f.sub.1 in cycles per second when tested in accordance
with test 13 of FIG. 15 herein before defined; said racket having a
length L in inches from the end of the grip portion to the end of
the head portion; said racket characterized in that the magnitude
of Ia is greater than 80 ounce inches squared; and the magnitude of
f.sub.1 is greater than 160 cycles per second and said length L is
greater than 25.5 inches. .Iaddend. .Iadd.48. A racket as in claim
47 wherein said netting has a width along a transverse axis
perpendicular to said longitudinal axis greater than 9.5 inches.
.Iaddend. .Iadd.49. A racket as in claim 47 wherein said netting
has a length along said longitudinal axis greater than 12 inches.
.Iaddend. .Iadd.50. A complete racket having at least a head
portion and a handle portion, said handle portion having a grip
portion suitably adapted for the hand to grip, the end of the grip
portion being located at the handle portion end of the racket; said
head portion supporting a string netting in a plane; said netting
having vertical and horizontal strings; said racket having a
longitudinal axis running from the center of the grip portion end
of the racket to the center of the head portion end of the racket,
said racket having a weight distribution providing for the moment
of inertia Ia in ounce inches squared about said longitudinal axis;
said racket having a weight and stiffness distribution providing a
frequency of vibration f.sub.1 in cycles per second when tested in
accordance with test 13 of FIG. 15 herein before defined; said
racket having a length L in inches from the end of the grip portion
to the end of the head portion; said weight distribution providing
for a center of percussion being located at a distance Cp in inches
from the end of the grip portion when tested in accordance with
test 4 of FIG. 15 herein before defined, said center of percussion
taken about a pivot located at the end of the grip portion, said
pivot having an axis perpendicular to the said longitudinal axis of
the racket and parallel to the plane of said string netting; said
racket having a center of gravity located at a distance Cg in
inches from the end of said grip portion; said racket having a
weight W in ounces; said racket characterized in that the magnitude
of Ia is greater than 80 ounce inches squared; the magnitude of
f.sub.1 is greater than 160 cycles per second; the product of said
weight W and said distance Cg given by the formula WCg is less than
160 ounce inches and said distance Cp is greater than 18.75 inches.
.Iaddend. .Iadd.51. A racket as in claim 50 wherein said weight W
is less than 10.7 ounces. .Iaddend. .Iadd.52. A racket as in claim
50 wherein the width of said netting is greater than 9.5
inches.
.Iaddend. .Iadd.53. A racket as in claim 50 wherein the length of
said netting is greater than 12 inches. .Iaddend. .Iadd.54. A
racket as in claim 10 wherein said racket has a weight means
located in the handle portion of the racket; and said racket
excluding said weight means having a weight and stiffness
distribution providing for a frequency of vibration f.sub.1 in
cycles per second when tested in accordance with test 13 of FIG. 15
hereinbefore defined, and said frequency f.sub.1 being greater than
160 cycles per second. .Iaddend. .Iadd.55. A racket as in claim 54
wherein said racket excluding said weight means has a weight being
less than 10.7 ounces. .Iaddend. .Iadd.56. A complete racket having
at least a head portion and a handle portion, said handle portion
having a grip portion suitably adapted for the hand to grip, the
end of the grip portion being located at the handle portion end of
the racket, said head portion supporting a string netting in a
plane, said netting having vertical and horizontal strings; said
racket having a weight W in ounces; and said racket having a weight
distribution providing for the center of percussion being located
at a distance Cp in inches from the end of the grip portion when
tested in accordance with test 4 of FIG. 15 herein before defined,
said center of percussion taken about a pivot located at the end of
the grip portion; a longitudinal axis running from the center of
the grip portion end of the racket to the center of the head
portion end of the racket, said pivot having an axis perpendicular
to said longitudinal axis and being parallel to the plane of said
string netting; said racket having a weight distribution providing
for the center of gravity being located at a distance Cg in inches
from said end of the grip portion; said racket having a weight
distribution providing for the moment of inertia Ia in ounce inches
squared about said longitudinal axis; said racket having a moment
of inertia I.sub.s in ounce inches squared taken about said pivot
located at the end of the grip portion, and I.sub.s is directly
proportional to the product of Cp, Cg, W given by the formula
I.sub.s =(Cp) (Cg) (W); said racket having an overall length L
along said longitudinal axis; said racket characterized in that the
distance Cp divided by the distance L given by Cp/L is greater than
0.70; and said moment of inertia Ia divided by said moment of
inertia I.sub.s given by Ia/Is is greater than 0.033. .Iaddend.
.Iadd.57. A racket as in claim 56 wherein said racket has a weight
and stiffness distribution which provides for a frequency of
vibration f.sub.1 in cycles per second when tested in accordance
with test 13 of FIG. 15 herein before defined and said frequency
f.sub.1 is greater than 165 cycles per second. .Iaddend.
Description
BACKGROUND OF THE INVENTION
The present invention relates to game rackets in general, and in
particular to a tennis racket having means for reducing the shock,
vibration, and muscular strain received by the player, when used by
the player in a game.
Prior art rackets having conventional weight and stiffness
distribution have considerable shock and vibration transmitted to
the player's hand, when the ball impacts the racket at locations
other than the center of percussion.
U.S. No. 4,165,071 issued to Frolow Aug. 21, 1979, provided a prior
art racket having an unconventional stiffness and weight
distribution which provided for a reduction in the shock and
vibration received by the player's hand upon impact of the racket
with the ball. The racket disclosed by Frolow was easy to move
because of its reduced weight, the torque or moment at the player's
hand when the racket was held by the player's hand as a cantilever
was reduced, the center of percussion was located closer to the
point on the racket string netting which was more frequently
impacted by the ball in play. This racket had the same hitting
power as conventional prior art rackets by maintaining the required
moment of inertia or swing weight.
However, when the ball did impact the racket at locations other
than the center of percussion, the player's hand absorbed the shock
and vibration which did occur.
The present invention utilizes the unconventional weight and
stiffness distribution of the racket disclosed by Frolow and also
provides a system comprising a weight means and a means for the
attachment of the weight means to the handle portion of the racket,
for reducing further the shock and vibration received by the
player's hand during the impact of the racket with the ball and the
vibration subsequent to the impact.
U.S. Pat. No. 3,941,380 issued to Lacost Mar. 2, 1978, provided a
weight means attached to the handle end of a racket. The weight and
restoring resiliency was designed to vibrate in correspondence to
the vibration induced in the racket, when the ball impacted the
racket. The weight means absorbed the energy at this single
frequency of vibration. The weight means disclosed must be designed
differently for each racket having a different structure.
The patent to Lacoste disclosed a racket having a conventional
weight distribution and it was very flexible and had considerable
vibration at a low frequency induced in it upon impact with a ball.
This racket had the weight of conventional prior art rackets, and
the additional weight means added by Lacoste results in a heavy
racket.
The present invention provides a weight means fastened to the
handle portion of the racket and the movement between the weight
means and the handle portion does not vibrate at the frequency
corresponding to the frequency of vibration of the movement between
the racket frame and the hand of the player, induced in the racket
when the racket impacts the ball. In column 4, lines 22 to 26
Lacoste indicates that if the frequency of the amortizing system is
less than 45 Herz one finds the difference between the frequency of
the amortizing system itself and the frequency of the frame is too
great to permit the amoritization to be significant. Since the
frequency of the frame f.sub.1 was 100 Herz, this difference
between the frequencies is 55 Herz, and thus a frequency of the
amortizing system itself outside the range of f.sub.1 .+-.0.55
f.sub.1, will not permit the damping to be significant. This range
cooresponds to frequencies less than 0.45 f.sub.1 and greater than
1.55 f.sub.1. The present invention provides a weight means which
absorbs the energy of the shock and vibration at all the
frequencies of vibration that occur.
Also the present invention provides for a racket having a light
weight, a center of percussion close to the center of the racket
face, a low torque at the player's hand, when the racket is held as
a cantilever by the player, the same hitting power as prior art
rackets, and a reduction over the prior art in the shock and
vibration transmitted to the player's hand upon the racket
impacting the ball.
U.S. Pat. No. 4,364,564 issued to Lewis Dec. 21, 1982, discloses a
device which is worn on a player's wrist to absorb the shock
experienced by a player in a game of tennis or the like. This
device does not interact directly with the racket which generates
the shock and vibration to the player's hand upon impact of the
ball.
The present invention absorbs the energy before it gets to the
player's hand and also reduces the shock and vibration generated by
the racket upon impact with the ball.
U.S. Pat. No. 4,153,249 issued to Plangenhoef May 8, 1979,
discloses slight mechanical modification to a conventional prior
art racket to make the racket more compatible with the mechanics of
the human arm, more comfortable to use and reduce the strain on the
arm of the player. This patent discloses a conventional prior art
racket with a weight attached to the handle end and a side weight
attached to one side of the head portion of the racket. The patent
discloses that the magnitude of the weights are adjusted to coact
and provide for the center of percussion taken about a center of
rotation which is located at 43/4 inches from the handle end, to be
located between 22/27 and 23/27 of the racket length from the
handle end of the racket, and the center of gravity to be located
at a distance slightly less than half the length of the racket.
The use of the side weight on one side of the racket head increases
the weight of the racket given by W, increases the distance of the
center of gravity to the handle end given by Cg, and increases the
moment of inertia of the racket about the handle end. These
increases result in the torque or moment at the handle end held in
the hand of the player as a cantilever given by the product WCg to
be very high, as well as make the racket difficult to swing and
maneuver. Conventional prior art rackets and the racket disclosed
by Plagenhoef have a high torque at the end of the racket handle
held in the hand of the player and the addition of this side weight
makes this torque more unfavorable. The racket disclosed by
plagenhoef has a weight W of 430 to 440 grams of 15.136 oz to
15.488 oz and the distance of the center of gravity Cg to be from
12 to 13 inches, thereby resulting in a torque given by WCg to be
182 to 197 oz-inches at the player's hand. These values are
exceptionally high.
The increase in weight to the conventional prior art rackets, makes
the racket difficult to maneuver. The racket disclosed by
Plagenhoef has a weight of 15.136 oz to 15.488 oz which is very
high.
The present invention provides for a racket having a torque given
by the product WCg, and a weight W which is much less than the
racket disclosed by Plagenhoef, and further provides for means
which effectively reduces the shock and vibration to the hand and
body of the player.
U.S. Pat. No. 3,999,756 issued to Head Dec. 28, 1976, discloses a
racket having a strung area having a length along the longitudinal
axis of the racket to be between 12 and 15 inches, and the width of
the strung area to be between 91/2 and 111/2 inches in a direction
perpendicular to the longitudinal axis of the racket.
The center of percussion of a racket similar to that of the racket
disclosed, the Prince GRAPHITE, taken about the handle end measured
to be 18.1 inches from the handle end.
The present invention provides for a racket having a strung area
having a width being greater than 12 inches, which is as large as
the racket disclosed by Head, but provides for a center of
percussion which is greater than 18.1 inches, and provides for a
weight much less than 12 ounces, thereby making the racket much
easier to maneuver, and providing for much less shock and vibration
being transmitted to the player, when the racket impacts the
ball.
SUMMARY OF THE INVENTION
U.S. Pat. No. 4,165,071 issued to Frolow Aug. 21, 1979, reduce the
shock and vibration by providing that the center of percussion be
located closer to the center of the racket face, where the ball
impacts the racket more frequently. As stated in col. 3, lines
61-63, the reaction at the handle end of the racket is zero when
the ball impacts the center of percussion. If the center of
percussion is 19.5 inches from the handle end and the ball strikes
the racket at head of the racket at 26.5 inches from the handle end
the reaction is ##EQU1## If the center of percussion were 18.0
inches, the reactive force R would be ##EQU2##
Thus there is a significant reduction in the shock experienced by
the player when relatively small changes are made in the distance
of the center of percussion from the handle end.
The addition of weight to the handle end held by the hand of the
player of the racket does not affect the torque or moment at the
racket handle end, when the player holds the racket as a
cantilever. The torque or moment being given by the product WCg
where W is the weight of the racket, and Cgis the distance of the
center of the center of gravity from the handle end. Since the
weight is added at the pivot located at the handle end, it simply
increases the weight W of the racket to the same degree that it
reduces the distance Cg so that the product WCg remains the
same.
The improvement discovered relates to the fact that a weight added
to the handle end does something else in addition to the changes
discussed above.
If a reactive force R is experienced at the handle end, this force
would tend to make the handle end accelerate or move. This instant
acceleration would be given by
where M is the effective mass accellerated by the movement of the
handle end, and A is the accelleration of the handle end.
Normally a player's hand is attached to the handle end and it would
absorb all of the reactive shock R. However, if a weight is
attached to the handle end, this reactive shock is shared by the
attached weight and the player's hand. Further, if the weight added
is composed of energy absorbing material that is loosely attached
to the handle end, it will absorb much of the shock and vibration.
Other energy devices may be used. A tube may be filled with a
liquid and a weight, a liquid alone, sand, lead pellets, etc. A
strip of energy absorbing material may be attached to the handle
end loosely, so that it will impact the racket handle wall when the
ball impacts the racket.
Further, rackets having a weight and stiffness distribution as
disclosed by the patent to Frolow, have nodal pivots in the handle
end located much further away from the handle end than conventional
prior art rackets. A racket having a node located at a large
distance from the handle end allows the hand holding the handle
end, and the weight means attached to the handle end by this
invention, to move easily balance the vibratory forces acting on
the other side of the node. That is, the node acts as a fulcrum in
a see-saw, the further away the forces at the handle end from the
fulcrum, namely the shock and vibratory forces generated by the
impact of the ball upon the racket.
Further, the patent to Frolow discloses on col. 10, lines 33-34,
that when a racket is struck, the racket will vibrate at a
frequency. The lower the frequency is the larger the amplitude of
vibration will be. Rackets utilizing the stiffness and weight
distribution disclosed by the patent to Frolow have a higher
frequency of vibration and a smaller amplitude of vibration.
The present invention utilizes rackets having the stiffness and
weight distribution disclosed by Frolow, thereby making the weight
means added to the racket handle much more effective in reducing
the shock and vibration transmitted to the player's hand. For
example claims of this application utilize claim 23 of the patent
to Frolow. Claim 23 requires, "said netting having a length along
the longitudinal axis of said frame greater than 9 inches and a
width along an axis perpendicular to said axis greater than 7.5
inches;". This claim further requires that the distance Cp be
greater than 18.75 inches and the weight W be less than 10.7 ounces
with appropriate language. Claims of this application make use of
the requirement stated in the quotation above.
Further prior art rackets having large strung areas, such as the
Prince Graphite racket, have a large moment of inertia about the
longitudinal axis of the racket. This increase in inertia has
provided for less torque to the player's hand when the ball impacts
the racket at distance from the longitudinal axis of the racket.
The large strung area requires a large perimeter for the strung
area and hence the weight would be larger than rackets having
smaller strung areas. However, by utilizing composite materials and
higher strength alloys the prior art has maintained the weight of
the head.
The weight distribution required by the large strung area also has
reduced the distance of the center of percussion taken about the
handle end of the raacket from the handle end.
The present invention by making structural improvements over prior
art rackets has provided a racket having an unconventional weight
and stiffness distribution as disclosed by Frolow, thereby allowing
for a racket having a large strung area being lighter than prior
art rackets and having less shock and vibration transmitted to the
player's hand upon impact of the ball on the racket. The reduction
in the shock and vibration transmitted is further reduced in the
present invention by the use of a weight means added to the handle
portion of the racket.
It is an object of this invention to provide a racket having a
weight means for reducing the shock and vibration which is
transmitted to the player's hand.
It is also an object of this invention to reduce the shock and
vibration transmitted to the player's hand when the ball impacts
the racket, by means of structural improvements in prior art
rackets which provide for the center of percussion being located
closer to the center of the racket face, and which provide for the
reduction in the weight of the racket over prior art rackets.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a front view of a racket according to the invention.
FIG. 2 is a crossectional view of section II--II.
FIG. 3 is a crossectional view of section III-III.
FIG. 4 is a crossectional view of section IV'IV.
FIG. 5 is a crossectional view of section V--V.
FIG. 6 is a crossectional view of section VI--VI.
FIG. 7 is an enlarged cut-away view of the handle end 7 containing
the weight means 8.
FIG. 8 is an enlarged cut-away view of the handle end 7 containing
an alternate weigh means 14.
FIG. 9 is an enlarged front view of the string member 4.
FIG. 10 is a side view of the string member 4.
FIG. 11 is a front view of a racket according to the invention
having a graphite composite handle 7A, and graphite composite head
side members 16. The top crown portion of the head being
aluminum.
FIG. 12 is a crossectional view of section XII-XII of 15.
FIG. 13 is a crossectional view of section XIII-XIII of 16.
FIG. 14 is an enlarged crossectional view of the junction of the
head portions 15 and 16.
FIG. 15 is a chart tabulating measurements on prior art rackets,
and on rackets made in accordance with the invention.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
FIG. 1 depicts a front view of a racket. The longitudinal axis of
the racket is shown as axis a--a in FIG. 1 running from the center
of the head portion end of the racket to the center of the grip
portion end of the racket. A transverse axis at the handle end of
the racket is shown as axis o--o in FIG. 1. The frame 1 is shaped
and formed from a hollow tube of 6061-T6 aluminum having a wall
thickness of 0.035 inches and an outside diameter of 0.75 inches
and a perimeter of 2,356 inches. The shape of the head portion of
the racket formed by the tube 1 comprising a crown portion and two
adjacent side portions, is an inverted tear drop shape having more
material toward the head end. The top crown portion is flatter than
conventional rackets. FIG. 2 depicts a cross-section which shows a
groove, which serves to protect the strings 2. FIG. 3 shows a
crossection at the head portion wherein the holes for the strings
are shown. Nylon grommets not shown can be used in these holes.
FIG. 4 shows a cross-section of the tube 1 which has been shaped
into a flat oval. The ends of tube 1 are inserted into the open end
of the handle member 7 and are fastened to the handle 7 with blind
rivets 5 through the gusset plate 6, which is a sheet of 7075-T6
aluminum 0.020 inches thick. FIG. 5 shows a cross-section view of
the handle 7 which has been shaped into a rectangular form, from
the hexagonal crossectional shape shown in FIG. 6 of handle 7. The
handle 7 is shaped from a rectangular sheet of 7076-T6 aluminum
which is 0.020 inches thick, having the overlapping edges fastened
together with blind rivets 5, which are not shown. The end of the
handle is covered with a plastic butt 9. A portion of handle is
covered with a suitable, thin, light grip, which is not shown. The
grip portion of the handle comprises the said portion of the handle
member 7 covered by said light weight grip material and the butt 9.
The grip portion end is located at the handle end of the racket.
The location of the axis o--o as shown in FIG. 1 is also at the
handle end of the racket. Inserted within the hollow handle 7, is a
weight means 8. FIG. 7 depicts the weight means 8, which consists
of a rubber tube 12 having the ends plugged with rubber discs 11.
The interior 13 of the tube 12 can be partially filled with a
liquid, sand, metal pellets or a combination of these. It can also
be filled with strips of energy absorbing material. Alternatively
the tube 12 need not be filled, but consist of a strip of suitable
energy absorbing material. The weight means 8 is attached to the
handle end by the wire 10, which allows free movement of 8 within
the hollow handle 7, so that 8 may strike against the side wall of
the handle 7, upon impact of the ball against the racket. FIG. 8
shows an alternative weight means 14, which is a lead or other
suitable metal. The metal 14 is shown fastened firmly against the
racket handle wall, but it can also be attached loosely so that it
may strike the handle side wall upon impact of the ball with the
racket. When the weight means 14 is firmly fastened against the
racket handle wall, responsive to a single impulse force to the
weight means 14, there is no significant motion between the weight
means 14 and the racket handle. When the weight means 8 is loosely
attached to the handle, responsive to a single impulsive force to
the weight means 8, the motion between the weight means 8 and the
handle portion does not oscillate between two extreme positions
from the said handle portion a plurality of cycles. The weight
means 8 and the weight means 14 both reduce the shock and vibration
received by the player. The weight means 8 shown in FIG. 7 is an
approximately three inches long and weighed 1.1 ounces. A much
shorter weight means can be used. The increase in the cantilever
moment WCg, that the weight means 8 adds is given by
(1.1)(1.5)=1.65 ounce inches. The increase to the moment of inertia
of the racket about the handle end is given by (1.1)(3.0/3).sup.2
=3.3 ounce-inches. Since the moment of inertia of the racket
labeled 13C is 2936 oz-in.sup.2, this increase is negligible. The
cantilever moment for this racket 13C is 152.68 oz-inches, so that
the increase is 152.68+1.65=154.33 oz-in. The changed center of
percussion distance Cp would be 2939.3/154.33=19.043 inches.
The center of percussion without the weight means 8 was 19.23
inches=2936/152.68
Thus the change was 0.182 inches.
A weight means 8 much shorter than 3 inches can be used so that
this change can be made smaller. From this discussion in can be
seen that if the weight means is moved away from the handle end of
the racket toward the head end, it becomes less effective in
absorbing the shock and vibration, it affects the cantilever moment
WCg, and also the distance of the center of percussion Cp.
Measurements were made on an embodiment similar to that shown in
FIG. 7. With the weight means and also without the weight means.
The results tubulated in the chart shown in FIG. 15.
Shown in FIG. 9 is a string member 4 which guides the central
vertical strings 2 away from the longitudinal axis of the racket to
terminate in the head member 1 at a greater distance from the
junction of the handle member 7 and the head member 1 than they
would, if they continued in a straight line. As shown in FIGS. 1
and 4, the angle formed by the two portions of the vertical strings
are approximately 45.degree., and this angle can be varied. This
may be advantageous in providing more flexibility in choosing the
spacing between the vertical strings. However, string member 4 need
not be used, and the vertical strings would then continue as shown
in FIG. 1 by the solid lines, and not be diverted as shown by the
dotted lines. FIGS. 9 and 10 show an enlarged view of the string
member 4. The string member shown is a hollow nylon tube which is
supported by the vertical strings 2, and the string member 4
provides guide holes 17 for the strings 2 to pass through. These
holes 17 maintain the spacing between the strings 2. The direction
of the forces exerted by the tension in these strings on the string
member 4, pushes the member 4 toward the head of the racket against
the lowest horizontal string 3. The central vertical strings keep
member 4 centrally located on the longitudinal axis. The string
member 4 is very light, is free to move with any movement of the
strings, and provides the proper spacing for the central vertical
strings. Many variations in the structure of the string member 4
may be made to accomplish the objectives as outlined herein.
The spacing between the vertical strings which are adjacent is
closer for those strings which are located closer to the
longitudinal axis of the racket, than the spacing for those strings
which are further away from the longitudinal axis.
The spacing between the adjacent horizontal strings are also closer
together for those strings which are located closer to the central
horizontal axis of the racket face than for those strings which are
located further away. This variable spacing provides for a
concentration of strings at the center of the racket face and
minimizes the trampoline effect which is common to rackets which
have a oversize or large strung area.
FIG. 11 depicts another embodiment of this invention. The crown
portion of the head portion of the racket 15 has the same contour
and crossectional shape as the crown portion of the head portion of
the racket shown in FIG. 1. It is also made from 6061-T6 aluminum.
However, it is not as long as the tube 1, and it joins member 16 as
shown in FIG. 11. The crown portion of the racket does not have its
weight reduced over prior art rackets, since sufficient weight is
required to obtain the desired swing weight, and weight located in
the crown portion moves the center of percussion toward the crown
portion of the racket. Thus the use of a composite material of
fibers and resin having great strength and light weight being a
major portion of the crown portion and resisting a major portion of
the mechanical forces which are resisted by the crown portion,
these forces resulting from the tension of the strings in the
string netting, is not employed. It is more advantageous to employ
less costly materials in the crown portion which are more easily
used in the fabrication of the crown portion such as metal, wood
and other materials. Member 16 is a graphite composite tube having
a diameter which mates with the diameter of the member 15. Although
FIG. 11 shows the head portion of the racket without strings on
string holes, it is understood that the head portion utilizes these
materials, and other materials which may be used in the manufacture
of the racket. The stretched strings exert mechanical forces on the
head portion of the racket which are resisted by the crown portion
and the side portions of the head portion. Member 16 comprises
substantially only one material and this material resists
substantially all of the forces which are resisted by the side
portions of the racket. This said material of member 16 is a
composite of fibers and resin. FIG. 12 and FIG. 13 show the tubular
shape of members 15 and 16. Members 16 terminate with the handle
member 7A, and their ends are fastened to 7A by means of blind
rivets and a gusset plate 18. The use of a graphite composite
member 16, reduces the weight of the racket in the middle portion
of the racket and thereby moves the center of percussion toward the
head of the racket, reduces the cantilever moment given by the
product WCg, and also reduces the weight of the racket. Each of the
side portions 16 comprise substantially only one material and this
material resists substantially all of the mechanical forces which
are resisted by the side portions, these forces resulting from the
stretched strings in the string netting. This said material is a
composite of fibers and resin which has great strength per unit
weight and also great stiffness per unit weight which permits the
reduction of weight in the side portions and yet provides adequate
strength and stiffness. Other materials may be employed in the side
portions for other purposes. Member 7A, the handle is also a
composite graphite material. The handle 7A has the same shape and
cross-sectional shape as the handle member 7 shown in FIG. 1. The
thickness of the wall of 7A is approximately the same as 7 with the
end portion in which the rivets 5 are used being thicker. However,
it is much lighter, stiffer, and stronger than 7. Another
embodiment of the invention is accomplished, when handle 7A is used
in lieu of handle 7 in the racket shown in FIG. 1.
FIG. 14 depicts a method of joining member 16 to member 15. Hollow
blind rivets 5 are used as shown and permit the strings to pass
through them to form the racket netting. Member 15 may comprise
wood as in prior art rackets, having the shape as shown in FIG. 11.
The end portions of members 15 and 16 can be tapered to allow the
racket string tension to further lock them together.
Measurements were taken on rackets similar to the embodiment shown
in FIG. 11 and to the embodiment shown in FIG. 1 wherein the handle
member 7A is used in lieu of 7. The results of these measurements
are tabulated in the chart shown in FIG. 15.
Tests and measurements were made on prior art rackets, and rackets
conforming to the requirements of this invention to show the marked
differences between them. The results are tabulated in the chart
shown in FIG. 15.
The various rackets tested are listed under col. 1 on the rows of
the chart as follows:
PRIOR ART RACKETS
Row 1. Prince Graphite
Row 2. Prince Professional an aluminum racket
Row 3. Heat Tournament Director an aluminum racket
Row 4. Durban, an aluminum racket
Row 5. Wilson Sting, a graphite racket
RACKETS IN ACCORDANCE TO THE INVENTION
Measurements were taken on the rackets without the weight means 8
shown in FIG. 1 first, then measurements were taken on the same
rackets with the weight means 8.
Row 7. #30C is a racket similar to the embodiment shown in FIG. 1,
utilizing the graphite handle 7 A shown in FIG. 11, in lieu of the
aluminum handle 7, without the weight means 8, being employed.
Row 8. #30 with the weight means 8 being employed.
Row 9. #32 is a racket similar to the embodiment shown in FIG. 11
but without the weight means 8 being employed.
Row 10. #32 with the weight means 8 being employed.
Row 11. #13C is a racket similar to the embodiment shown in FIG. 1,
having the aluminum handle 7, but without the weight means 8 being
employed.
Row 12. #13C with the weight means 8 being employed.
Row 13. #13C with weight means 14 being employed.
The weight means 8 shown in FIG. 7 employed in the rackets listed
in rows 9, 11, and 13 was three inches long, weighed 1.1 ounces and
space 13 was partially filled with sand.
The weight means 14 shown in FIG. 8 employed in the racket listed
in Row 14 was 1.48 ounces, 1 inch wide and lead.
Other rackets than those listed in the chart of FIG. 15, conforming
to the requirements of this invention have been fabricated. For
example a racket similar to the embodiment shown in FIG. 1 having a
contour and crossectional shapes as disclosed in FIG. 1, was
fabricated of composite graphite, that is, the head member 1 and
the handle member 7 utilized composite graphite. Also rackets
similar to the racket disclosed in FIG. 1, but having a smaller
width for the string netting were made, such as #3XC which is
listed in rows 14 and 15 of FIG. 15. Further, weight means 8 and 14
having weights greater and less than used with the rackets listed
in the chart of FIG. 15 were employed. For example if a weight
means such as 14 or 8 having a short length as previously indicated
and having a weight of 3.0 ounces were employed with racket #32C
the increase in WCg would be 3.0.times.0.5=1.5 ounce-inch. The new
WCg would then be 148.4+1.5=149.9 oz-inches, which is practically
unchanged. The new weight W would be 8.78+ 3.0=11.78 ounces. The
increase in the moment of inertia I.sub.s would be 3.0(1).sup.2
/3=1 ounce-inches. The new I.sub.s would be 2956+1=2957
ounce-inches.sup.2, which is practically unchanged. The new Cp
would be 2957/149.9=19.73, which is practically unchanged. Thus it
is possible to adjust the weight of a racket to be as heavy as is
desired without affecting the center of percussion Cp, the swing
weight or moment of inertia I.sub.s, or the moment WCg of the
racket significantly. The heavier the weight means 8 or 14 used,
the more the shock and vibration received by the player's hand will
be reduced. All the rackets with these variations performed
well.
The rackets listed in rows 7 through 15 were hand made. With the
use of proper tools and facilities for heat treatment, forming,
punching, and moulding of composite materials improvements in the
performance of these rackets should be obtained.
The tests and test methods employed on the rackets listed in the
chart of FIG. 15, are the same as those used and described in col.
15 of the U.S. Pat. No. 4,165,071 to Frolow and are as follows:
Col. 1 Designates the racket tested.
Col. 2 L, the length of the racket in inches.
Col. 4 Cp, the distance of the center of percussion from the handle
end of the racket. The racket is supported at a pivot at the handle
end. The racket is caused to swing as a pendulum having a small
amplitude for more than 10 consecutive swings. The time T in
seconds is measured for the pendulum to compete 10 swings. The
center of percussion distance Cp in inches is given by the formula
Cp=9.79T
Col. 6 Cg, the distance of the center of gravity from the handle
end of the racket in inches.
Col. 7 W, the weight of the racket in ounces.
Col. 7 WCg, The product of Col. 6 and Col. 7.
Col. 10 Is, The moment of inertia about the axis 0--0, in
ounce-inches.sup.2.
Col. 11 Ia, the moment of inertia about the longitudinal axis a--a
in ounce-inches.sup.2.
Col. 13 fl, the frequency in cycles per second of the vibration
perpendicular to the racket face with the ends free, and the racket
is held at the nodal pivot near the handle end of the racket. This
mode of vibration has a node near the handle end of the racket and
a node in each side of the head portion of the frame near the head
end of the racket.
Col. 14 Dl, the deflection perpendicular to the racket face, in
inches, of the middle of the racket between the ends when a weight
of 80 ounces is applied to the middle of the racket, and the racket
is supported six inches from the handle end of the racket, and the
head frame sides are supported at points opposite the center of the
face.
Col. 15 The distance in inches of the node closest to the handle
end, from the handle end of the racket associated with the
frequency fl. The racket is held between the forefinger and thumb
in the vicinity of the node located in one side of the head portion
of the frame. The racket is tapped repeatedly with a rubber tipped
hammer along the longitudinal axis of the racket in a direction
perpendicular to the face of the racket, in the vicinity of the
node located near the handle end. The location at which the minimum
amplitude of vibration occurs when tapped having the frequency fl,
is the precise location of the node.
It is understood that variations and modifications may be made in
the embodiments of the invention within the spirit of the present
invention and the scope of the appended claims.
* * * * *