NL8502690A - Jump ball for exercising - has inflatable flexible body with groove to receive peripheral annular plate - Google Patents

Abstract

The ball has an inflatable ball body of elastic material and a rigid annular plate. In the inflated condition of the ball body it is coupled with the annular plate (2) by interlocking male and female profile parts of the ball body and plate. The profile part on the ball body is integral with the body. The profile formations prevent relative axial movement of the ball body and plate. The female profile in the ball body consists of a circular groove (3), of which the bottom is inward of the opening. The groove can be V-shaped in cross-section.

Description

NO 33434 Springball

The invention relates to a spring ball consisting of an inflatable ball body of elastic material and a rigid annular plate, which, in the inflated condition of the ball body, is clamped in the annular plate, of which spring ball, at least the ball body is made in a form, such as a rotational mold.

Such a spring ball is generally known and is shown and described, for example, in Netherlands Patent Application 10 7005221, which has been laid open to public inspection and in U.S. Pat. No. 3,716,229. These known jumping balls consist of an inflatable ball-shaped body, which is made of an elastic material, for instance an elastic plastic, such as polyvinyl chloride. The manufacture of such a ball body takes place by means of a rotational molding in which the ball wall of the ball body is formed by placing plastic in a heated mold and distributing it evenly over the inner wall of the mold under the influence of the centrifugal forces.

The annular plate can consist of any suitable sufficiently rigid material, but is usually manufactured from plastic in an injection mold. A suitable plastic is polyethylene.

In the known spring balls, the connection between the annular plate and the ball body takes place either by welding these parts together or solely on the basis of friction.

Welding has the drawback that it requires an extra action with the risk that weak spots occur in the wall of the ball body or that the connection between the elastic relatively soft plastic material of the ball body and the hard plastic material of the plate is not of sufficient quality everywhere. is.

The most applied is therefore the frictional connection, which arises because the ball body is clamped in the opening of the plate during inflation and as a result of expansion, whereby bulges form above and below the plate, so that the plate with its inner edge clamp is in a constriction, which is thus formed in the ball body.

35 Balls are used as toys or sports equipment. During the use of the jump ball, very large loads can occur, which must be absorbed by the weld or friction connection between plate and ball body. If the pressure in the ball body falls, which will always be the case after some time, there is a risk that the annular plate suddenly shoots off the ball body, as a result of which not only 5 µf. 0 & «λ vw v 4 0 ü

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2 the plate and the user standing thereon fall down, but also the ball body, which is still under tension, shoots out of the annular plate with great force, which may lead to further accidents. These have indeed taken place, in particular when the ball body uses it as a sports item.

The object of the invention is now to provide a spring ball in which the connection between the ball body and the annular plate is such that without a welding connection a tight connection is nevertheless established that detachment is impossible. Another object of the invention is to achieve this regardless of the shape of the ball body, so also with a ball body that does not have a constriction obtained by pumping it up.

This object is achieved according to the invention in that, in the inflated condition of the ball body, this ball body is coupled to the annular plate by means of interlocking male and female profile parts of the male and female profile parts of the ball extending in the axial direction of the ball. ball body resp. the plate of which profile parts the profile part, which is situated on the ball body, is integral with the ball body and consists of the same material.

The interlocking profile parts now ensure an absolute confinement of the ball body in the ring under all circumstances, including when pressure is reduced.

In principle, two solutions are conceivable.

According to the invention it is thus possible for the female profile to be located in the ball body and to consist of a circumferential groove, the bottom of which lies inwardly of the mouth of the groove, into which groove the male profile of the plate fits.

Conversely, however, it is also possible for the female profile 30 to consist of a groove in the inner edge of the plate and the male profile to consist of a cast-on radially projecting flange.

Many forms of the interlocking profile parts are conceivable here. For example, the groove may be U-shaped in cross-section, dovetail-shaped or have a growth base, which is at an angle to the vertical center line of the ball body. The inner edge of the plate fitting in the groove naturally has a corresponding shape, so that it fits well in the groove.

If a flange is applied to the ball body, it may also be rectangular, dovetail or chamfered in cross section, and 40 of this shape will fit into a complementary shaped groove in the inner section; 9 3 0 3 edge of the plate.

When using a groove in the ball body it is further useful that, viewed in cross-section, the legs of the groove have a wall thickening at their outwardly facing ends. This not only improves the clamping of the edge of the plate, but also increases the moment of resistance of the groove profile against deformation.

When a radial flange is applied to the ball body, this flange, as it merges into the ball body, will form, as it were, a circumferential T-shaped profile, which profile profile also has a great resistance to bending.

The invention will now be further elucidated with reference to the drawings.

Fig. 1 shows in section a first embodiment of the jump ball according to the invention.

FIG. 2 shows in cross section another embodiment of the jumping ball according to the invention.

Fig. 3 is a sectional view of a third embodiment of the jump ball according to the invention.

Fig. 4 is a cross-sectional view of a further embodiment of the ball-body in the non-inflated state with solid lines and the dashed state in broken lines.

Fig. 5 shows part of a mold for making the jump ball of FIG. 4.

Fig. 6 and 7 schematically show in cross-section variants of the flange connection of the embodiment of fig. 3.

Fig. 1 shows a spring ball 1 in the inflated condition to which is attached the annular plate 2. This spring ball, like that of the other embodiments, is made in a rotational mold. This form is provided with an internal profiling, as will be further elucidated in Fig. 5, whereby a U-shaped groove 3 is formed in the wall of the ball body. This groove has radially outwardly extending legs 4 and a base 5. The legs have thickenings 6 at their ends, the outer surface of which is almost perpendicular to the plate 2.

At 7 there is a valve for inflating the ball.

In the inflated condition shown in Fig. 1, the U-shaped groove portion is radially expanded such that it completely encloses the inner edge of plate 2. This confinement is not only in the radial direction, but also completely in the axial direction. i.e., in the direction 40 of the vertical ground line 8 of the ball body. The load takes place SS 0 2 8 9 0 4 in directions which correspond substantially and form small angles with those of the center line 8 or with uneven load on the two sides of the plate.

It is clear from the drawing that even with some pressure drop 5 a very good confinement is obtained.

By inflating the ball, the cross section has been given a vort, which is referred to as an eight shape, and which consists of more or less spherical bulges under and above the plate 2, respectively.

It will further be clear that in the non-inflated state 10 the ball body can be easily inserted into the opening of the plate 2.

Fig. 2 shows an embodiment in which the ball body 10 is spherical in the inflated state. This ball body is also manufactured in a rotational molding such that a circumferentially extending groove 11 is formed, which, however, is dovetailed in cross section. Also here, as a result of the manufacturing process, thickenings 12 are formed at the ends of the legs of the groove. The plate 13 has a profile on its inner edge that fits into the dovetail groove.

The embodiment of fig. 3 is a ball body, which is again shown in the pumped-up state, but which is provided on its periphery with a flange 14 rectangular in cross section, which fits into a groove 15 of the annular plate 16. This plate 16 has a flat top surface and on the underside, in order to save weight, is made in known manner with recesses 17 and reinforcing ribs 18.

Fig. 6 shows that the flange in the associated groove can have a dovetail profile 19.

Fig. 7 shows that the flange can have a profile chamfered at 20.

FIG. 4 shows a ball body 21 in the non-inflated state as it is supplied by the mold. This ball body is provided with a circumferential groove 22, which in this embodiment has a bottom 23, which in this embodiment has a bottom 23, which forms an angle with the vertical center line 8 ', which groove cooperates with a chamfered inner edge 24 of a annular shelf 25.

The pumped-up tooth, so that the inner edge of the plate 25 and the groove 22 interlock, is indicated by broken lines 21 *.

Fig. 5 shows the lower half of a rotational molding mold 26 for manufacturing the ball body 21 shown in FIG. 4. The upper half of this mold 85 is not shown. It has an edge which connects to the edge 27 of the mold 26 and an internal spherical shape, which continues the internal spherical shape of the lower half 26. A ring 28 is placed in this mold half 26. This now determines the shape of the groove 22, the embodiment shown in fig. 4. If the embodiment of fig. 4 is now compared and if the profile of the wall is continued on either side of the groove, it can be seen that by the shape of the ring 28 automatically forms thickenings 29 and 30 during the rotation process.

In the embodiment of Fig. 4 and therefore also in the mold shown in Fig. 5, the groove is in a plane transverse to the vertical centerline located below the horizontal plane through the center of the ball body.

When it comes to the manufacture of a ball body, as shown in, for example, fig. 1 or fig. 2, a ring will also be present at the height of the central part surface of the mold, which determines the profile of the groove and therewith also of the thickenings 6 resp. 12.

In the embodiment of Figs. 3, 6 or 7, the mold wall, where the flange is to be formed, is provided with a circumferential recess, which is filled automatically during the rotation process.

For the sake of completeness, it should also be noted that the manufacture of a spring ball by means of the rotation process with foot supports which are formed integrally and thus cast on is known per se from British patent specification No. 1,297,8337. Footrests integral with the ball body, however, have the drawback that, due to the large radial dimensions of the footrests, the mold becomes very expensive and the footrests themselves must be made of the same material as the ball body and are therefore relatively slack.

3502630

Claims (11)

1. Spring ball consisting of an inflatable ball body of elastic material and a rigid annular plate, which in the inflated condition of the ball body is clamped in the annular plate, of which, at least the ball body, the ball body is manufactured in a form, such as a rotatable ball. die-cast, characterized in that in the inflated condition of the ball body this ball body is coupled to the annular plate by means of interlocking mandrel and female profile parts of the ball body or circumferentially extending in the axial direction of the ball, respectively . the plate from which profile parts the profile part, which is situated on the ball body, is integral with the ball body and consists of the same material. 2. Spring ball according to claim 1, characterized in that the female profile is located in the ball body and consists of a circumferential groove, the bottom of which lies inwardly of the mouth of the groove, into which groove the male profile of the plate fits. Spring ball according to claim 2, characterized in that the groove is U-shaped in cross section. 20 Spring ball according to claim 2, characterized in that the groove is dovetail in cross section. Spring ball according to claim 2, characterized in that the groove 25, viewed in cross section, has a bottom which is at an angle to the vertical center line of the ball body. 6. Spring ball according to one or more of the preceding claims 2 to 5, characterized in that, viewed in cross-section, the legs of the groove have a wall thickening at the location of their outwardly facing end. Spring ball according to claim 6, characterized in that the wall thickening has an outer surface which is almost perpendicular to the plane of the plate. 35 Spring ball according to claim 1, characterized in that the female profile consists of a groove in the inner edge of the plate and the male profile consists of a cast-in radially projecting flange. 8 55 0 9 fi ï! fï 7 ' Spring ball according to claim 8, characterized in that the flange is rectangular in cross section. Spring ball according to claim 8, characterized in that the flange is dovetail-shaped in cross section. A jump ball according to claim 8, characterized in that the outer edge of the flange is chamfered. 35 0 2 6 9 0