SE441495B - JOJO TYPE TOY - Google Patents

Description

8204686-3 ___, j 2 Jojon causes a special problem for children or inexperienced users. Usually the yo-yo lifts over to one side and then begins to rotate around the axis of the string. When that happens, the jojo is out of control. This problem is due to precession and is the most serious problem with yo-yo use.

When a rotational force is applied to a rotating body and the force tends to displace the original axis of rotation, the body will react by rotating about an axis which is perpendicular to both the original axis of rotation and the axis along which the torque is applied. This phenomenon is called precession and has been studied intensively in connection with gyroscopes and top spinners, but not in connection with a yo-yo. The direction of the rotation caused by the precession can be predicted with knowledge of the original spinning direction and knowledge of the direction of the applied torsional force. Experiments which form the basis of the invention have been made with yo-yo toys and the experiments have confirmed that the primary difficulty in using a yo-yo is due to the precession phenomenon.

This precession rotation usually occurs around an axis which lies in the direction of the string.

The use of a yo-yo would be significantly simplified if the precession problem was eliminated or in any case reduced. One way to achieve such elimination is reduction is to use a yo-yo supporting material which has a marked resistance to rotation about an axis, directed along the length of the support member, but which is at the same time sufficiently reflective to be able to be wound around the yo-yo axis. Such a support or support member will prevent precession rotation about the axis of the support member.

In the following description and in the claims, the term "torsion-resistant support member" means a support member for the yo-yo body which causes a significant obstacle or prevents rotation around the longitudinal axis of the support member in comparison with conventional yo-yo strings previously used in commercially available yo-yo devices. In order to be able to support the yo-yo body, such a rotation-resistant support member must of course be flexible around axes across the longitudinal axis of the support member in order for the support members to be able to be wound up on the yo-yo axis. 3 8204686-3 An indication of the improved function of the new jojon is that the user finds that the jojon can be handled rather carelessly during use and full control of the movement is still maintained. The ability of the support member to counteract rotation about the longitudinal axis prevents the yo-yo from entering a precession rotation and also facilitates a return of the yo-yo body should such a precession movement occur.

Disclosure of the invention The toy according to the invention comprises a single shaft, which connects two parallel discs, the centers of which are connected to the shaft. In one embodiment, the torsionally resistant support member is attached to the shaft, thereby preventing the ion from spinning. In another embodiment, the rotation-resistant support member is placed in a loop around the shaft and thereby the ion can spin.

In describing the torsionally resistant support member associated with the ion shaft, the following terminology is used: "attached to" means that the rotation resistant support member is attached to, anchored to or embedded in the shaft to prevent the ion from spinning; "looped" means that the torsionally resistant support member loosely surrounds the shaft in such a way that the ion can spin; "connected to" means that the rotation-resistant support member cooperates with the shaft in either of the two possible ways, ie that it is fixedly connected or lies in a loop around the shaft.

In a particular embodiment of the invention, a system of one or more swivel members or players is attached to the end of the rotation-resistant support member opposite the end of the support member which connects to the shaft. A retaining ring is attached to the swivel system. To use the preferred embodiment of the invention, the user passes a finger through the retaining ring. After the support member is wound up around the shaft, the body of the yo-yo may fall downwards and then a slight upward and downward swinging movement is performed to keep the yo-yo body in rotation and thus facilitate its vertical upward and downward movement. If a swivel system was used, and; . . . . .w..í ______-___ - ___._ - _-- 8204686-3 this includes one or more swivels, an equalization of torsional forces in the support member, caused by rotation about a vertical axis, will be equalized. This also significantly facilitates the use of the toy. In accordance with the above description of the invention and the following description, it is a main object of the invention to provide a toy consisting of a shaft, two discs with their center points supported on the shaft and a rotation-resistant support member connected to the shoulder.

Yo-type toys according to the invention thus comprise a first disc, the center point of which is connected to one end of a shaft and a second disc, the center point of which is connected to the other end of a shaft and a flexible, elongate support member, one end of which is connected. to the shaft between the first and the second disc and wherein the toy is arranged to perform a combined rotational movement around the shaft and a translational movement along the support member. The essential feature of this toy is that the support member is torsionally resistant to counteracting rotation about the longitudinal axis of the support member.

According to the invention, the support member consists, for example, of a metal strand, a chain or a band.

The invention is described in more detail in connection with the accompanying drawings.

Figure description Figure 1 Figure 2 Figure 3 Figure Figure 5 Figure 6 is a front view of the phenomenon, is a front view of measuring and comparing means¿ is a front view of comprising one is a front view of comprising one is a front view of 8204686-3 a yo-yo, which illustrates a precession apparatus designed to resist the torsional resistances of different carriers of an embodiment of the invention, torsionally resistant string members, an embodiment of the invention, carriers in the form of a strip, a further embodiment of the invention, comprising a strip-string combination, and is a front view of an embodiment of the belt-string combination according to Figure 5, in which the string extends along the entire length of the strip segment.

Preferred Embodiments Before presenting the present yo-yo with twist-resistant support means described in detail by the preferred embodiments, it should be pointed out that it is understood that the invention is not limited to the particular embodiment of the details shown and therefore these may of course vary.

It is also understood that the terminology used has been added to describe special embodiments. and as such implies some limitation- 8204686-3- s Pig. 1 illustrates the precession phenomenon in connection with a rotating yo-yo body. The yo-yo body is generally referred to as 1.

The body comprises a single shaft 2. The shaft 2 has a pair of identical discs 3 mounted with their center points on the shaft 2.

It is assumed that the yo-yo body 1 rotates about the axis 5-5 so that the "+" symbols on the discs 3 indicate that these parts of the discs move upwards from the plane of the drawing and that the "-" symbols indicate that corresponding parts of the discs 3 move downwards in figure- f planet. The string 4 is pulled to the side and tends to rotate the body 1 in the clockwise direction, as indicated by the arrows 6 in Fig. 1. It is a well-known physical law that when a rotational force is applied to a rotating object, a tendency will arise to displace. the original axis of rotation and the rotating object will rotate about an axis which is perpendicular both to the original axis of rotation and to the axis of the applied force. This induced rotation is called precession. In connection with a rotating yo-yo according to Fig. 1, which is subjected to a torque according to this figure, the yo-yo body 1 will rotate or precede around an axis along 7-7 and the direction of precession is indicated by the curved arrow 8. If either the direction of rotation around the axis 5 -5 or the direction of the input torque, indicated by the arrows 6, is reversed, then the precession rotation will also be reversed and the rotation takes place in the opposite direction than that shown by the arrow 8.

The phenomenon of precession has been discussed and studied intensively recently. In particular, the precession of rotating spinners has been studied extensively, and reference may be made, for example, to "Spinning Tops and Gyroscopic Motion" by J. Perry (1850-1920), Dover, New York (1957), "An Elementary Treatment" of the Theory of Spinning Tops and Gyroscopic Motion "by H. C Crabtree, Longmans, Green and Co., London (1923) and" A Treatise on Gyrostatics and Rotational Motion "by A. Gray 1918, published 1959 by Dover, New York . In addition, the phenomenon has been covered in various newspaper articles. On the other hand, there are no known studies in the literature that relate to the precession of yo-yos. When a yo-yo falls out of control, it rotates largely around the axis of the string. Oddly enough, it appears that this rotational movement has not been attributed to precession for the explanation given in U.S. Patent Nos. H 290 22k, No. H 318 2U3, No. U H37 261 and No. H HU2 B25. Precession movement of yo-yo around the axis of the string has not been discussed in any available U.S. patent. U.S. Pat. No. 3,175,326 mentions the rotation of the yo-yo around the axis of the string, and this does not mean that the precession phenomenon has been observed. This patent discusses the use of inertia rings in yo-yo. However, it is important to note that regardless of the actual moment of inertia of the yo-yo body, precession will always occur, as illustrated in Fig. 1, when a force is applied to the body 1, and which force tends to reorient the original axis of rotation.

A number of commercial yo-yo toys are equipped with "inertia rings" or flywheels, but this cannot solve the problem of precession, but can on the contrary aggravate the problem.

The inventor is not aware of any other patents or any other literature relating to precession in connection with a yo-yo, as discussed above in connection with Fig. 1. The specific information, which includes drawings, and which is illustrated in Figs. 1 has been experimentally tested on yo-yo bodies and is in full accordance with the physical principles of precession (see, for example, Fig. 9.20 in "University Physics" by Sears and Zemansky, 4th Edition, Addison-Wesley Publishing Co., (1970); or Figs. XXII (p. 10) or Fig. 19 (p. 37) in "An Elementary Treatment of the Theory of Spinning Tops and Gyroscopic Motion" by H. Crabtree, Longmans, Green and Co., 1923 (originally printed 1909). the effect is caused by precession and not by anything else.

The precession of the ion, which is marked by the curved arrow 8 in Fig. 1, can be counteracted by applying a torsional force in the opposite direction to the arrow 8. Such torsional force can be produced by the string H, if the string is capable of producing a torsional resistance. against rotation. Conventional yo-yo strings offer very little resistance to twisting and 8204686-3 x. Contribute extremely little to preventing precession of the yo-yo body. The inventive concept is based on the design of support members which have a significant torsional resistance and as such are thus able to counteract the tendency towards precession of the yo-yo body. Apart from the content of the above-mentioned American applications, nothing has been mentioned about the phenomenon. In particular, the use of torsion-resistant support members for yo-yo bodies has not previously been specified or indicated. U.S. Patent No. H 318 ZU3 discloses an alternative method of avoiding the precession problem in yo-yo toys.

I have discovered that replacing the unconventional yo-yo string or yo-yo string with a twist-resistant support member radically counteracts the precession problem and leads to an extremely large improvement in the function of a yo-yo.

According to the invention, furthermore, a swivel system consisting of one or more swivels, which are mounted on the support member on the opposite side of the shaft, will further improve the function of the ion. The invention results in a yo-yo-type toy which is easier to use than a conventional yo-yo, which can be used even by very young children and by completely inexperienced adults.

These improvements are obtained due to the torsional resistance to rotation of the material in the support member, which in connection with the yo-yo body constitutes the invention. An example of a torsion-resistant support material which is particularly effective is a type of torsion-resistant strand, called a metal strand.

Metal strands consist of fibers of fibers, around which thin or flat metal wires or simulated metal wires are woven. Such a material is commercially available and is relatively inexpensive. One type of such material is produced by KNITRIMS of Miami, USA (2431 N.W. 2nd Avenue, Miami, Florida, 33217). One type of metal cord consists of "LUREX", which is woven around multiple strands of rayon fibers. Another type of torsion-resistant material consists of thin chains, for example of the type used by jewelers. Such chains offer great resistance to twisting, but can nevertheless be easily wound up on a yo-yo shaft. According to the invention, furthermore, a tape or a tape can also be used to advantage. In the event that a tape or strip is used, in addition to the torsional resistance to twisting, additional effects can be obtained which contribute to an improved function of the ion, as will be described later. The attachment of a swivel member or a swivel member, which comprises a retaining ring, means a significant improvement with respect to the function and handling of the new ion.

It should be noted that the above-mentioned specific torsion-resistant support members are mentioned by way of example only and that the invention is not limited to these specific embodiments and the mentioned products, but thus by torsion-resistant support member is meant any member which meets the requirements for torsional resistance. and which is suitable for yo-yo.

Conventional yo-yo strings have very low torsional resistance. The main idea according to the invention is to use a rotation-resistant support member alone or in combination with a swivel device. The clear improvement with respect to the function of the yo-yo according to the invention over a conventional yo-yo is obvious to any person practicing the invention. However, it is desirable to be able to measure the torsional resistance of the support members according to the invention in order to be able to show quantitatively that they differ significantly from conventional yo-yo strings.

In order to be able to quantitatively state the torsional resistance of different types of support members for a yo-yo body, an apparatus of the type illustrated in Fig. 2 was developed. This apparatus can be used for strings, strips and the like. The use in connection with the strings or strings is first described and then a description is given of its application to ribbons or strips.

The means 9 and 10 are vertical supports which are connected by means of an upper connecting means 11 and a lower connecting means 2.

The members 13 and the shelter consist of vertical bars, which are attached to the supports 9 and 9, respectively. 10. Lens discs 15 and 16 are slidably mounted on the rods 13 and lie by means of clamps 17 and 17, respectively. 18.

A hook 19 on the upper connecting member 11 carries the string. The string 20 is provided with a split ring 21 ho: its lower end. The string 20 is connected via the ring 21 to a cylindrical strut 22 of known diameter by means of a hook 23, which is screwed into the rod 22. A weight of 2% is attached to the lower end of the rod 22. A light wire 25 connects to the cylindrical rod 22. The wires 25 lie in the groove of the pulley 15 and a known weight or mass 26 hangs down from the wire 25. A wire 27 is attached to the rod 22 on the opposite side of the wire 25. The wire and wire 27 are attached to the rod 22 at slightly different vertical levels, as indicated in Fig. 2. The wire 27 lies in the groove of the disc 16 and has a known weight or mass 28 hanging in the wire. Weights 26 and 28 are identical. Two series of parallel holes 29, 30 are arranged in vertical sequence along the support members 9, 10. The plane containing these groups of holes lies slightly in front of the plane containing the rods 13 and 14. A releasable pin 31 can be inserted with its ends in the corresponding pair of holes.

The described apparatus was used in the following manner. The support member or string to be examined hangs in the hook 19, as shown in the figure. The rod 22 is rotated a number of turns in a selected direction released from the string and the direction here is assumed to be clockwise, if one looks from the top down towards the rod 22.

As a result, the wires 25 and 27 will be wound from the rod 22 in the same direction and thereby lift up the two weights 26 and 28. These weights exert a torsional force or a moment on the rod 22, which torsional force tends to rotate the rod in the opposite direction to the , in which the rod was originally rotated.

After the rod 22 has been rotated a certain number of turns, it is coupled to the string 20 by means of the ring 21 and the hook 23. The torsional force exerted by the two weights 25 and 28 causes the rod 22 to rotate counterclockwise, seen from above, and thereby, the string will likewise be rotated in this direction.

The rod 22 and the applied weight 2D will rotate until the counter-torque produced by the twisted string is exactly equal to the magnitude of the torsional force produced by the weights 26 and 28, and this means that equilibrium is reached.

If the wires 25 and 27 are completely wound by the rod 22, the procedure is repeated again by disconnecting the rod 22 from the string 20 and again turning it manually in a clockwise direction as seen from above. During this twisting, the twisted strand is prevented from opening by inserting the pin 31 through the ring 21 while the ends of the pin 31 are supported in the holes 29 and 30. In total, the total mass hanging from the string 20 is the sum, of the weights of the ring 21, the hook 23, the rod 22 and the weight 2H, and this produces a tension in the string.

The torque or torques imparted to the rod 22 by the weight 26 are products of the weight 26 and the radius of the rod 22.

An equally large torsional force is produced by the weight 28. Since the two weights are equal, since both forces act in the same direction, the total torsional force will be the product of one weight x the diameter of the rod. The weight of the wires and the radius of the wires can be disregarded in these calculations, as they contribute to a very small extent to the measurement result. The distance between the two ends of the strand generally becomes smaller during the rotation, and consequently the clamps 17 and 18 are used to adjust the pulleys and 16 so that the wire segment 25 between the rod 22 and the pulley 15 and the wire segment 27 between the rod 22 and the pulley 16 lie horizontally in front. the execution of the final measurement. The torsional resistance of the different strands was compared by counting the number of turns that a given length of the string was twisted at a specific torsional force. The greater the number of rotational turns produced by a particular string at a given torsional force, the less torsional resistance is produced by the string. In all these measurements a rod 22 with a diameter of 6, H mm was used and the two suspended weights 26 and 28 weighed either 1 g or 2 g each. All experiments were thus performed with a total torque of 6.4 g mm or torque of 12.8 g mm. Measured values for a number of string materials are reported in Table I. All results are the average of at least six separate measurements. The equilibrium position was approached from both directions in all attempts to compensate for frictional forces in the device. All individual readings were within 5% of the mean, which indicates a good reproducibility and precision of the measurements.

Some strings, and especially the conventional double-stranded or loop string, have different torsional resistances clockwise resp. counterclockwise direction and in these cases the number of 8204686-3 11 revolutions in Table I indicates the average value for clockwise and counterclockwise rotation direction ~.

TABLE I Length Suspended weight Torque Number of revolutions String type (mm) (in grams) (in mm) Duncan Yo-Y 3) 1060 29.63 12.8 ~ 90 string _ .- _ CIS * FeSÉ1Selection YO YO 1029 29.63 12 , 8 90 string _ Duracraft Yo-Yo string 972 29.63, 12.8 see Metal string 1022 29.33 12.8 0.8 Metal string_ 1041 29.33 12.8 0, H Go Duncan Yo-Yo String 1118 52, 12.8 56 Metal string 1118 51.85 B, H 0.13 Metal string 1105 51.85 B, H 0, U0 braided "Yl °" "1092 52.15 s, u ao string (llkp) The yo-yo strings found The values in Table I indicate that typical yo-yo strings have a length of about 1000 mm and that, when subjected to a tensile stress of about 30 g, they will take up about H0 turns of rotation, when they are subjected to a torsional force of 12.8 g mm and are rotated more than revolutions when they are subjected to a torsional force of 6.4 g mm at a tension of about 50 g, measured in the manner described above.

The torsion-resistant strands according to the invention rotate less than 40 whole revolutions at a torque of 12.8 g mm and a tension of about 30 g and rotate less than 20 whole revolutions at a torque of about 6, H g mm and a voltage of about 52 g.

Pig. 3 illustrates an embodiment of a yo-yo with a twist-resistant string. In this embodiment, the twist-resistant strand 32 with a loop 33 lies around the shaft 2, thereby allowing the ion to spin. Alternatively, the twist-resistant string 32 can be fixed to the shaft 2, thereby preventing spinning effect. ss 8204686- The apparatus shown in Fig. 2 was also used to measure the torsional resistance of various strip materials.

When you easily twist a band, you create a form of type "spiral staircase". However, if you strongly twist the band, this shape collapses and folds form over the width of the band.

Bands differ significantly from each other with respect to the resistance to this type of coincidence, ie have substantially different torsional resistances. As the crease forms, the strip loses a significant portion of the torsional resistance. In cases where a weight hangs in the lower end of the strip, ie if the strip is subjected to tensile stress, its total torsional resistance will increase, ie the collapse of the "spiral staircase" does not take place until a large torque is applied to the system. However, this is not due to the inherent torsional resistance in the strip material itself, but depends to a large extent on the applied stress. Consequently, in experiments with belts, it is desirable to keep the belt tension as small as possible by making the total suspended mass as small as practically possible. For this reason, the weight 2H (Fig. 2) was not used in the belt experiments. The torsional resistance of different strips was compared by gradually increasing with the mass of the two weights 26 and 28, i.e. by gradually increasing the torque applied to a certain strip length and it was noted: (i) how many revolutions were applied to the strip at each torque and (ii) the magnitude of the moments that first caused a collapse of the "spiral staircase" shape.

The weights 26 and 28 can be conveniently changed by tying small plastic bags to the ends of the strands 25 and 27 and known weights can then be added and removed from these bags.

In all experiments a rod 22 with a diameter of 6.4 mm was used and the plastic bags each weighed 0.19 g. In these experiments the support 21 was flat instead of round to be able to receive the strip and weighed 0.37 g. 22 plus the hook 23 had a weight of 2.08 g. The tensile stress in the strip due to the šzoasße-5 1 »mass of the support Q1; the rod 22 and the hook 23 thus amounted to 2, H5 g. The strip was supported on its upper end by an elongate flat member connected to the hook 19.

Measured data for a number of strip materials are shown in Table II. The third column in Table 2 indicates the number of turns; The number of turns of each strip at a certain torque and 1.2 / 7.6 indicates that the strip has been rotated a total of 1.2 turns from the upper end to the lower end at a torque of 7.6 g mm. Column R indicates the minimum torque, which causes the "spiral staircase" shape of the belt to collapse.

All experimental results are means and at least three separate measurements; The equilibrium position was taken from both sides in all experiments to compensate for friction in the measuring device. All individual readings are very close to the mean, which indicates an extremely good reproducibility and precision of the measuring instrument.

The commercially available tapes or tapes of the different types have slightly different widths. However, it was possible to choose combinations which had relatively identical dimensions for comparison and as an example it can be mentioned that the first four strips in Table II have substantially the same width and that the fifth, sixth resp. The seventh strip in Table II is also very close to each other in terms of width, which enables a good comparison.

TABLE II Width Speed / torque Collapse point Strip (mm) (1 g mm) (g mm) satin to 1.2 / 7.6 10.9 satin 22 1.6 / 7.6; 2, u / 1u 20.3 Taffefa Plaid 25 1.7 / 7.6; 2.7 / 1u 15.2 Grosgrain 24 0.9 / 7.6; 2.05 / 20.3; 2.92 / 32; 3.93 / 51.8; - _ n, s / su, s 7s, 2 'MYLAÉÉ 19 2,5 / 7,6. 14 Twill strip 19 2.0 / 7.6 8.9 Grosgrain 17 1.6 / 7.6; 3.1 / 20.3; u, u / ss; 5.3 / us .7 55.9 All strips were 1067 mm long. Many of the conventional strips, such as twill strips, MYLAR, satin or Taffeta Plaid strips with the dimensions and structure commonly available, do not exhibit any pronounced degree of torsional resistance to rotational rollers and consequently, these materials are not particularly effective in connection with a yo-yo. As shown in Table II, typical textile strips (satin, Taffeta Plaid) with widths between cza 22 and 25 mm cannot absorb a torque of cza 25 g mm under a tension of 2.45 g, while a torque of approx. 75 g mm is required for a strip of Grosgrain in corresponding dimensions (1067 mm long and 2H mm wide) to collapse, ie the said 'spiral staircase "shape collapses in one plane. Correspondingly, a strip of twill or MYLAR with a length of 1067 mm and a width of cza 19 mm not to be able to accommodate a moment of cza 18 g mm, when a weight of 2, H5 g is supported, but a corresponding Grosgrain strip (1067 mm long and cza 17 mm wide) Although all torsional resistance is essential in the context of the invention, it is extremely important that the strip does not collapse, since a collapse of the strip during the use of the ion may make a correction impossible.

An embodiment of the present invention comprising a yo-yo body coupled to a belt or strip forming the support member is shown in Fig. H. In this embodiment the discs 3 are at a greater distance from each other than before and thus form a wider groove 3U. A flat strip or band 35 with the width 36 with one end connected to the shaft 2. The strip 35 is connected to the shaft 2 in such a way that when the strip 35 is fully extended, the edges 37 of the strip will be perpendicular to the shaft 2.

A fold 38 is located on the opposite end of the strip 35. This folding is secured by sewing machine stitching, weaving, riveting, gluing, etc. A stirrup 33 is mounted in the formed loop 38. A swivel system 40, which comprises one or more swivel means, is connected to the stirrup 39. The swivel system 40 allows the stirrup 39 and the strip 31 and the yo-yo body 1 to be rotated. The swivel system H0 also facilitates the removal of torsional jerks and the like. on the strip 30 as it is rotated about a vertical axis. 8204686-3 .OI-II lay 'H hires'' i 'to un' | r ~ - Vn- 't' '' A ring H1 to hold the ion is connected to the swivel system _. The whole device can be held by to stick a finger through the ring 41. V The strip 31 may consist of a large number of different flat and elongate materials of natural fibers or of synthetic type. The materials which will be included in the strip S may include leather, leather, felt, jute, holes, various types of leather, fiberglass, various textile materials, such as e.g. wool, silk, cotton, linen, satin, velvet, etc. and / or synthetic plastics or polymers, such as, for example, polyester, polyethylene, polypropylene, polyolefins, nylon, acrylic plastic, rayon, acetate or various mixtures of the abovementioned materials. The strip 35 may have parallel sides, as shown in Figs. H, 5 and 5, or the sides of the strip 35 may be non-parallel. The strip 35 may have a woven character or it may consist of a non-woven material. However, it has been found that wholesale grain tape or tape is particularly well suited for use in connection with the present invention. The essential feature of this material is that a strip with a sufficiently large torsional resistance is obtained. S.k. Grosgrain strip is characterized by a corrugated fabric pattern with grooves and grooves that run perpendicular to the sides 37 of the strip 35. This type of strip has a very significant ability to prevent rotation around the longitudinal axis, compared to most textile strips. Thus, when a grosgrain or coarse-woven strip is subjected to a torsional force, it tends to remain undistorted. If the yo-yo is swung to the side during use in a direction parallel to the axis 5-5, it will be subjected to a strong gyroscopic precession around the vertical axis. The rotation which is induced in the strip as a result of this precession rotation is quickly prevented by a grosgrain strip, and the strip thus remains distorted. This obstacle to rotation is achieved in part by the rotation of the yo-yo body 1 in the opposite direction to the rotation which was initially effected by the precession. In addition, the swivel system H1 is extremely efficient in relieving the rotation as a result of the torque caused by the twisted frame. Another advantage of using the grosgraín strip is the ability to hold f? 8204686-3 it straight along the entire width 36 and prevent wrinkling or skew along the width direction. If the strip is subjected to such a force that it is rotated about a vertical axis, which causes the strip to have the said "spiral staircase" shape, then the corrugated lines will still be horizontally aligned and thereby the shaft 2 is maintained in a horizontal position.

Grosgrain tape is especially suitable for use in a yo-yo.

Of course, other materials, such as twill strip, MYLAR, satin, plaid fabric, etc. can be made torsionally resistant by increasing the thickness beyond the conventionally occurring thicknesses or other modifications of the structure or by special treatment. The desired character of a strip used in connection with a yo-yo is that it has a significant torsional strength. Starting from Table II, a belt-type support member suitable as a yo-yo belt shall have the following characteristic torsional resistance: A belt length of 1067 mm and a width of 2H mm shall, under a tensile stress of 2, H5 g, withstand a moment of 25 g mm or more without collapsing, ie without the "spiral staircase" shape being flattened. A piece with a length of 1067 mm of a material with a width of 17 mm and a tensile force of 2, N5 g must be able to absorb a moment of cza 18 g mm or more without the spiral collapsing. However, it has also been found that when a swivel system is used in connection with the toy, strips with substantially lower torsional resistance than those mentioned above can be used.

It has been found that two characteristics of the invention contribute to an improved function, namely: (1) the torsional resistance of the yo-yo strip and (2) a swivel, which triggers any rotation that may occur. Experiments with various embodiments of the invention have shown that the best results are obtained when using a torsionally resistant strip in combination with a swivel. However, good results can also be obtained by using only a torsion-resistant strip or by using a swivel in combination with a strip which does not have any particularly pronounced torsional resistance. The best results are obtained by using a swivel in combination with a strip with a torsional resistance of such a nature that a strip segment with a length of 1067 mm is used in connection with the present invention.

E? and a width of 2Ä mm underwenhens tension of 2, H5 g can counteract a torque of 25 g mm or more without the torsional turns collapsing. However, good results have been obtained with such a strip without a swivel or by using a swivel with a strip which has a torsional resistance of such a size that a strip segment with a length of 1067 mm and a width of 24 mm does not With the term swivel according to the above means any member which allows a free can take up a torque of 25 g mm without collapsing. winding each twist of the strip in the same way as a conventional yo-yo string, which has no twisting resistance.

The strip 35 can be anchored to the shaft 2 by dividing this shaft 2 into two parts along the entire length, the strip 35 being inserted between the two shaft halves. The strip 35 can be held in this position by applying adhesive, by wedging the strip etc. around the shaft 2, so that the yo-yo body can spin freely.

Alternatively, the strip 35 can be placed in a loop Pig. 5 illustrates a spinning modification of the invention. In this modification, a strand segment H2, which is joined to the strip 35 in the form of a loop 33, lies around the shaft 2. The shaft 2 is provided with a ring groove 43 for holding the strand segment centrally on axeln 2.

The string H2, which was not used as a replacement for the swivel HO, can consist of any of a large number of string materials, natural or synthetic. The type of string material conventionally used for a yo-yo is the kind, ie they consist of twisted threads. string is especially suitable in case it has to be doubled in order to A beaten shape an eye around the shoulder for a yo-yo with spin possibility. A wound string with two threads twists very effectively around itself and forms an eye or loop. This type of string is very effective. Other types of strings such as braided nylon or sail yarn, hemp, cord, etc. can also be used according to the invention.

It should be noted that the torsion-resistant strand, such as for example metal cord, is particularly effective in connection with the invention for connecting the strip 35 to the shaft 2 as illustrated in Fig. 5, but cannot replace the swivel H0.

Another embodiment of strip / string combination is shown in Fig. 6, in which the string UH is laid in a loop around the shaft 2 and the string UH enters at one end 45 of the strip or band 35 and leaves the band at the opposite end 46. In this case, the movement of the loop 33 around the shaft 2 is controlled in the same way as in a conventional yo-yo.

If a yo-yo with support means in the form of a strap according to Fig. 4 is used, the suspension of the shaft 2 along the entire width 36 of the strip 35 will further facilitate the use of the toy. By winding the strip 35 on itself during the operation of the toy, a smoother movement is obtained than is the case when a conventional string yo-yo is used, in which the string is wound on top of itself in a rather irregular manner and which can cause the winding turns to slip. from each other during the winding process.

A further characteristic feature of the strip is that when the yo-yo body is subjected to a precession movement, the strip will act as a barrier or "sail", which exhibits a marked air resistance, and thereby the precession rotation of the yo-yo body will also be absorbed. Also in this case, a strip that can withstand collapse of occurring windings is desirable.

The use of a band or strip 35 allows one to achieve decorative and visual effects, which are not possible to achieve with conventional yo-yo strings. You can, for example, write, draw or apply color markings, etc. on the strip or the strip can be made of a luminescent or fluorescent material to make the toy even more attractive. A strip-supported yo-yo according to the invention provides a significant visual image in contrast to a conventional yo-yo.

The yo-yo of the present invention is used in substantially the same manner as a conventional yo-yo. The string 32 (Fig. 3) or the strip 35 (Fig. U) or the strip-string device 35 plus H2 (Fig. 5) can be wound around the shaft 2 by hand. In the case of an embodiment with a spinning yo-yo body, the loop 33 must be used to be sufficiently tightened around the shaft to catch it during winding. To start the yo-yo movement, the yo-yo body 1 is held in one hand and the end of the string 32 or strip resp. the holding ring 41 is held with the other hand. Thereafter, the body 1 of the ion is allowed to fall freely while continuing to hold the end of the string 32 or strip 35, respectively. rings H1.

As the yo-yo body 1 falls downwards, the body 1 will be caused to rotate about its axis 2 thereby winding the twist-resistant support member from the shaft 2. When the twist-resistance support member has been completely wound up, the yo-yo body 1 has a substantial rotational moment. If the support member is attached to the shaft, this torque will cause the yo-yo body 1 to continue to rotate, and thereby the support member will be wound up on the shaft 2 in the opposite direction as before. Jojon's body 1 will consequently rise upwards after the support member. A slight upward movement, which is imparted to the support member just before the body 1 reaches the lowest point during its downward movement, enables the upward and downward movement of the yo-yo body 1. This force impulse compensates for both friction losses and loss in the translation component, which later occurs when the yo-yo body has reached the lowest position, and in connection with the body being caused to change the direction of translational movement.

If the yo-yo body is of the spinning type, i.e. when the shaft 2 lies in a loop 33 on the string or strip, the moment of rotation of the yo-yo body 1 at the lower turning point will allow the yo-yo body to continue to rotate in this position, i.e. it spins, until its kinetic energy consumed by friction. However, if the spinning yo-yo body is brought out of the spinning position by a slight jerk, the yo-yo body will again move upwards along the support member and the rise height depends on the amount of kinetic energy still present in the yo-yo body. The spinning joion can be brought out of its spinning state by a jerk in the support member or alternatively by reducing the tension in the support member.

The main advantage of yo-yo according to the invention over a conventional yo-yo and modifications of such a yo-yo is the elimination of or return to normal after the appearance of a gyroscopic precession.

If, for example, during the use of the yo-yo according to the invention, it is pivoted laterally, i.e. in a direction parallel to the yo-yo axis 5-5, it is subjected to a gyroscopic precession about a vertical axis, and this phenomenon is common to all types of yo-yo and in the known ones it entails a total loss of control over the movement of yo-yos. With a yo-yo according to the invention, which is provided with the rotation-resistant support member and possibly in connection with the swivel system, the precession rotation will counteract and the arising problem will be eliminated quickly and automatically.

It is possible to manufacture the body 1 from a large number of different materials such as for example wood, plastic, metal, rubber compositions etc. The yo-yo body 1 can be cast or turned to form a coherent unit or the discs 3 and the shaft 2 can be manufactured separately and then joined with each other in different ways, for example by gluing, via threads, pressing in, soldering, welding, etc. The shaft 2 does not have to be provided with the groove H3. One of the modifications, which comprises a torsionally resistant string and has been found to work very efficiently, comprises two discs, each 57 mm in diameter, which are 2.5 mm apart by means of a shaft with a diameter of 6 mm. The string consists of a piece of metal cord 1.2 cm long, manufactured by KNITRIMS of Miami (2431 N.W. 2nd Avenue, Miami, Florida 33127, USA) and anchored to the shaft by one end of the string being clamped between the shaft and one of the discs. Such yo-yo works well even when it is suspended in a swivel system, which for example consists of the type of toy used on fishing gear and a holding ring.

If a strap supports the yo-yo body, it has been found that a strap with a width of 16 mm works particularly well, as the strap consists of ribbed woven polyester, ie so-called grosgrain, and which is connected to a shaft with a diameter of 6 mm, which in turn is connected to disks with a diameter of 52 mm.

A swivel system is connected to the other end of the strip or belt and a retaining ring is fitted to the swivel system.

When joion is assembled by inserting the strip or band between two shaft halves, the circumference of the shaft should be slightly elliptical instead of circular, and this is especially desirable, since one can thereby compensate for the "bubble" which occurs where the band goes out from the shaft, and such an elliptical shaft results in a very smooth unrolling.

The invention has been shown and described in connection with previous embodiments, however, it is obvious that deviations from these embodiments can be made without departing from the inventive concept and that certain modifications are obvious.

Claims (5)

Q, 8204686-3 P A T E N T K R A V A yo-yo toy, comprising a first disc (3), the center point of which is connected to one end of a shaft (2) and a second disc (3), the center point of which is connected to the other end of the shaft (2), and a flexible, elongate support member (32, 35), one end of which is connected to the shaft (2) between the first and the second disc and wherein the toy is arranged to perform a combined rotational movement about the shaft (2) and a translational movement along the support member (32). 35), characterized in that the support member is torsionally resistant for counteracting rotation about the longitudinal axis of the support member. 2. A toy according to claim 1, characterized in that the support member comprises a string (32) which is resistant to rotation, for example a metal string. 3. A toy according to claim 1, characterized in that the support member comprises a chain resistant to rotation. A toy according to claim 1, characterized in that the support member comprises a strap (35). A toy according to any one of claims 1-H, characterized in that between the support member (35) and the shaft (2) there is a wire (H2) or a swivel device (H0).