GB2053697A - Pressurised play balls - Google Patents

Abstract

A playball, e.g. a tennis ball, is pressurised with sulphur hexafluoride or halogenated hydrocarbon gases, and has an internal surface (3) profiled by a multiplicity of depressions or protuberances (4), the outer surface (2) of the ball being smooth. The profiling is in the form of dimples or pimples of circular plan view, intersecting ridges, or rectangular blocks, and is provided to prevent the ball from emitting a "pinging" noise when bounced. <IMAGE>

Description

SPECIFICATION Play ball This invention relates to pressurised playballs, i.e.

play balls made with a rubber core inflated with a gas at a super-atmospheric pressure. It is particularly concerned with tennis balls but is not limited thereto and is applicable, for example, to Racquet balls.

It is well known that pressurised play balls gradually lose pressure over a period of a few months until they eventually become unsatisfactory for use.

This occurs due to the permeation of the inflating gas through the wall of the ball and one method of overcoming this disadvantage is-to store the balls inside pressurised containers until they are required for use. While this is in fact normal current procedure, storage in this way is both inconvenient and costly.

An alternative method of overcoming the basic problem of loss of pressure is to produce balls which do not need internal pressurisation and methods of making tennis balls of this type are described in British Patent Specifications Nos. 1.108.555, 1.108.557. Non-pressurised tennis balls have never been universally accepted by good tennis players due to certain shortcomings in their performance and there is therefore a need for an improved pressurised tennis ball which can be stored for long periods of time without the necessity for special pressurised packaging.

It is known that certain gases when used for inflating balls permeate through the ball wall more slowly than either air or nitrogen, which are conventionally used for inflation purposes. These slow permeators are basically gases of relatively large molecular size and/or complex molecular geometry.

One gas which appears to offer an advantage in this respect is sulphur hexafluoride (sub) and also mixtures of this gas with air or nitrogen.

Certain other gases also show a similar advantage in reduced rate of pressure loss, for example perfluoropropane (C3F8) and Cl2CFCF3. Use of such slow permeating gases in pressurised play balls has been described in British Patent No. 1.543.871 and South African Patent No. 73/8777.

However, one significant disadvantage has been found in using gases of relatively large molecular size in that, on bouncing, balls so inflated often exhibit a significant high-pitched noise which can be disturbing to players. This is particularly so in tennis when players bounce the tennis ball on the court surface immediately prior to serving at a time when their mental concentration must not be subject to distraction.

It would appear that the high-pitched noise is a condition of resonance of the core and its inflation gas and the fact that the nature of the gas is found in certain circumstances to promote this resonant condition is thought to be due to the interaction of the internal dimensions of the core and the wavelength of vibrations produced in the gas by the deformation of the core and its subsequent vibrations after bouncing. (By 'core',herein is meant a hollow elastomeric sphere which may be either the well-known core of a tennis ball or the complete ball of, say, a Racquetball ball).

Be that as it may, we have found that if the internal surface of the core is given a profiled, rather than a smooth surface, then the high-pitched noise is reduced or eliminated.

The present invention accordingly provides a play ball comprising a hollow elastomeric sphere pressurised with a gas of low permeability, the internal wall surface of the sphere being profiled by a multiplicy of depressions or protuberances but the outer wall surface of the sphere -being substantially smooth.

As indicated above, the invention is of particular relevance to tennis balls and so for convenience will hereafter be described with particular reference to tennis balls.

Although it is not intended to limit the invention to any particular theory, it is thought that the reduction or elimination of the high-pitched noise referred to above may be due to the following reasons: During the local deformation of the ball on bouncing, compression waves are set up in the inflation gas which are reflected back and forth across the inside of the core and under certain conditions standing waves will be produced which give rise to the high-pitched noise. Such effects are well known in relation, for instance, to organ pipes in which the length of the organ pipe determines the frequency of the vibration of the air contained within it and where the closed end of the organ pipe causes compression waves to be reflected and standing waves to be set up.

In the case of an article such as a tennis ball core the considerations are altogether more complex.

The frequencies of the standing waves are determined by the internal dimensions of the core and the molecular weight of the gas contained therein. Also the core itself vibrates and has a resonant frequency which is determined by the rubber composition of which it is formed, thethickess of the wall of the core and the pressure of the inflating gas.

Under certain circumstances, if one of the stand- ing wave frequencies in the gas coincides with one of the core vibration frequencies, reinforcement will occur giving rise to a resonant condition for the core/gas system which is evidenced by large amplitude vibration at that frequency. The vibrations will exist for a finite time due to the conditions of resonance and will be clearly audible.

The addition of, say, dimples or pimples to the inner surface of the core alters the effective internal diameters of the core measured through different points on the internal surface of the core. This will have the effect of producing more complicated internal reflections so that the formation of standing waves inside the core is inhibited and the likelihood of a resonant condition being produced is minimised.

A secondary effect of the dimples or pimples may be that the stresses induced in the core wall when the ball is bounced and which govern the vibration of the core itself are modified by the varying effective thickness of the wall of the core and so the resonantfrequency ofthe core itself is changed to a value that is less critical in relation to the frequency of the standing waves generated inside. The vibration induced in the system on bouncing the ball therefore dies away much more quickly and so is less audible and under certain circumstances, no undesirable high-pitched sound is produced whatsoever.

It should be pointed out that normally the internal surface of the core of a tennis ball is made as smooth as possible forthe following reasons: - 1) The wall thickness should be as uniform as possible so that uniform bounce is obtained.

2) Stress concentratipns leading to wall failure could occur under certain conditions of nonuniformity.

3) The core is usually made by assembling together two half-cores. The half-cores are made by a compression moulding process and difficulty could be experienced in removing the half-core from the mould if it had a profiled surface.

4) The necessary profiled surface of a half-core mould would be more difficult to clean than that of a mould with a smooth surface. This is due to the build-up of residues that occur during.the moulding process.

The above points (1) to (4) indicate why in normal practice half-core moulds have smooth insides.

However, if necessary, and despite the possible disadvantages, internal profiled surfaces can be specified which provide advantages in avoiding resonance as previously indicated, but which minimise other problems.

As suggested previously, the multiplicity of protuberances or depressions produces a highly nonuniform reflecting surface so that standing waves are avoided.

The depressions or protuberances are preferably a large number, e.g. from 40to.400, especially from 80 to 150, of dimples or pimples and these are preferably uniformly distributed.

The profiled inner surface of the core can be obtained in ways otherthan by dimpling or pimpling. For instance, the profiling may be produced by incorporating a number of ridges, grooves or blocks on the internal surface or by producing indentations or protuberances of varied shape and distribution.

From these considerations of practical manufacture however, dimples or pimples are generally preferred particularly when it is considered that they allow complex reflection of sound waves and yet affect the weight of the core least. This is an important factor because in addition to the other important properties of a tennis ball, i.e. rebound, compression (or hardness) and. size, weight must be held within strictly controlled limits.

Normally between 10% and90% of the internal surface area should be constituted by, e.g. dimples or pimples, and preferably between 25% and 75%.

The dimples or pimples are preferably of circular appearance in plan view, their shape being that a solid of revolution generated by the rotation of a plane curve about a radius ofthe core, such as a segment of a sphere organ ellipsoid, but this is by no means essential. Their dimensions are not critical but preferably the ratio of diameter to depth/height should be as large as possible and preferably equal to or greater than 2:1. Preferred dimple or pimple diameters are from 3.0 mm to 8.0 mm, e.g. 6.0 mm and preferred depths- or heights are from 1.0 mm to 3.0 mm, e.g. 1.5 mm.Whichever type of depression or protuberance is utilised, it is preferred that its height or depth should not be greater than 3.0 mm (0.125 inch) from the internal surface level ofthe core for a core of thickness (excluding any depression or protuberance) of 3.3 to 3.7 mm.

The following factors should be taken into consideration when determining the degree of profiling that may be used with advantage for any particular circumstances.

1. A generally roughened or pitted surface should not besuitable because it would render the mould extremely difficult to clean.

2. The texture must therefore be in the form of a number of distinct indentations or protuberances.

3. The weight limitations on the ball core will be an overriding factor as to the total volume of indentations or protuberances that can be tolerated.

4. Other than fairly regular curved shapes of indentations or protuberances may not be satisfactoryfortwo reasons: (a) any undercuts would lead to difficulties in removal from the mould, (b) any sharp angles could lead to undesirable stress in the product.

5. The depth of any indentation will be limited by the requirement to maintain a minimum strength based on a minimum wall thickness.

The tennis ball core may be moulded from any conventionally-used elastomeric materiai and may be covered with, e.g. melton or needled-punched fabric.

The initial internal pressure of the tennis balls is preferably in the range 10 to 12 p.s.i. and the balls should meet the specification is laid down by the International Lawn Tennis Federation: Diameter - "Go-No Go" gauge 2.575" to 2.700" (65.4-68.6 mm) Weight 2.0 - 2 1/16 oz (56.70. - 58.47 gm) Rebound from 100" onto concentrate 53-58" (1.35 - 1.47 m) Deformation under 18 Ib f (8.2 Kgf) load 0.230 0.290 in (5.85 - 7.35 mm) Deformation under 18 Ib f (8.2 Kgf) load on recovery after ball has been compressed through 1".

(2.54 cm) 0.355 - 0.425 in (9-10.8 mm).

Various embodiments of the invention are illustrated by way of example only in the accompanying drawings in which: Figure 1 shows a tennis ball core with part of the wall removed to show the internal configuration according to one embodiment of the invention, Figure 2 shows a fragment of the wall of a tennis ball. core, partly in section, showing an alternative embodiment of the invention, Figure 3 is a similar view to Figure 2 of a further embodiment of the invention, and Figure 4 is a similar view to Figure 2 and Figure 3 of a yet further embodiment of the invention.

Figure 1 shows a hollow tennis ball core 1 having a smooth, indentation-free outer surface 2 and a dimpled inner surface 3. The dimples 4 formed in inner surface 3 of the core are uniformly distributed over surface 3 and are circular in plan form. Their shape as seen in cross-section is that a solid of revolution generated by the rotation of a plane curve about a radius of the core.

The wall thickness of the core measured between dimples, i.e. in an undimpled area of the core, was 3.5 mm and the dimples were 7 mm in diameter and 2.5 mm in depth. Eightly-two dimples of this size and shape are uniformly distributed over the inner surface of the core whose internal diameter, again measured between dimples, was 52.5 mm. Hence 27% of the surface area of the interior of the core was constituted by the dimples.

When filled with SF6 to a pressure of 12 p.s.i. the core was covered with a conventional melton and used as a tennis ball. No noticeable 'pinging' noise was detected. A similar size core of the same material when similarly inflated with SF6 and simi larly covered resulted in a tennis ball emitting a distinct 'pinging' noise on bouncing.

Figure 2 shows an alternative embodiment in which instead of dimples, pimples 5 are uniformly distributed over the inner surface 3 of the core.

In Figure 3 the indentations or protuberances are in the form of ridges 6 and 7 standing proud of surface 3 and in Figure 4 blocks 8 are uniformly distributed around and stand proud of surface 3.

Claims (15)

1. A playball comprising a hollow elastomeric sphere pressurised with a gas of low permeability, the internal wall surface of the sphere being profiled by a multiplicity of depressions or protuberances but the outer wall surface of the sphere being substantially smooth.

2. A playball according to Claim 1, in which the pressuring gas is SF6, C3F8 or Cl2CFCF3.

3. A playball according to Claim or 2 in which there are from 40 to 400 depressions or protuberances uniformly distributed.

4. A playball according to Claim 3, in which there are from 80 to 150 depressions or protuberances uniformly distributed.

5. A playball according to any one of the preceding claims, in which from 10% to 90% of the internal wall surface area of the sphere is constituted by the depressions or protuberances.

6. A playball according to Claim 5, in which from 25% to 75% of the internal wall surface area of the sphere is constituted by the depressions or protuberances.

7. A playball according to any one of the preceding claims, in which the depressions or protuberances are dimples or pimples respectively or circular appearance in plan view.

8. A playball according to Claim 7 in which the shape of the dimples or pimples is that of a solid of revolution generated by the rotations of a plane curve about a radius of the sphere.

9. A playball according to Claim 7 or 8, in which the ratio of diameter to depth or diameter to height of the dimples or pimples respectively is equal to or greater than :1.

10. A playball according to Claim 7,8 or 9 in which the dimple or pimple diameters are from 3.0 to 8.0 mm and their depths or heights are from 1.0 mm to 3.0 mm.

11. A playball according to any one of Claims 1 to 6, in which the profiling is in the form of ridges or grooves on the internal wall surface.

12. A playball according to any one of Claims 1 to 6, in which the profiling is in the form of blocks on the internal wall surface.

13. A playball according to any one of the preceding claims, which is a tennis ball, the sphere constituting the core of the ball.

14. A tennis ball according to Claim 13, in which the wall thickness of the core excluding any depression or protuberances is from 3.3 to 3.7 mm and the depths or heights of the depressions or protuberances are not greater than 3.0 mm.

15. A playball according to Claim 1 substantially as hereinbefore described with reference to and as shown in the accompanying drawings.