KR20160045582A - Constructional toy - Google Patents

Abstract

A constructional toy comprises a plurality of elements (10, 40, 40′, 60, 100, 300, 202, 302, 304, 400, 500). The elements can be assembled together to form a variety of three dimensional rotatable structures. The elements comprise a first gear wheel element (10, 40, 40′, 60, 400, 500). The first gear wheel element has a side wall (14) which forms a side face of the first gear wheel element and a circumferential edge (16) of the first gear wheel element. A plurality of gear teeth (18) are provided around the circumferential edge of the first gear wheel element. The gear teeth are driveably engaged with a second gear wheel element having gear teeth in a complementary shape to the gear teeth of the first gear wheel element. A first opening part (20) provided in the side wall to accommodate a drive element (100, 200, 202) is also provided. In use, the drive element driveably engages with a gear wheel through the opening part to provide a means for transferring a force to the first gear wheel element to rotate the first gear wheel about a rotational axis which is aligned with or coaxial with a central rotational axis of the first gear wheel.

Description

CONSTRUCTION TOY

The present disclosure relates to a configurable toy.

A number of configurable toys for children are typically available. These toys have a wide range to meet the developmental needs and abilities of children, whether for play or education. These toys not only enhance coordination but also contribute to a better understanding of basic machine operations.

Therefore, there is a great need for configurable toys that can be used by children in various developmental stages to further enhance and enhance machine operation skills and understanding.

According to the present disclosure, there is provided an apparatus as set forth in the appended claims. Other features of the invention will be apparent from the dependent claims and the following detailed description.

Accordingly, a configurable toy comprising a plurality of elements may be provided, the plurality of elements may be assembled together to form various three-dimensional rotatable structures, the element including a first gearwheel element, The first gear wheel element comprising: a side wall defining a side surface of the first gear wheel element and a peripheral edge of the first gear wheel element; A plurality of gear tooth rows about an outer circumferential edge of the first gear wheel element, the plurality of gear teeth rows being operatively engageable with a second gear wheel element having a gear tooth row in a shape complementary to the gear tooth row of the first gear wheel element Gear teeth; A first opening provided in the sidewall and configured to receive a drive element, the drive element being operable, in use, with a gear wheel via the aperture to provide a means for transmitting a force to the first gearwheel element To rotate the first gear wheel about an axis of rotation that is aligned with or coaxial with the center rotational axis of the first gear wheel.

The first opening may be offset from a center rotational axis of the first gear wheel.

The first opening may be coaxial with the central axis of rotation of the first gear wheel.

And the second opening may be provided offset from the first opening.

A third opening may be provided offset from the first opening and the second opening and at least two of the apertures may extend from the rotational axis to form a pitch circle diameter centered on the rotational axis, They can be spaced the same distance.

The first, second and third openings may be aligned such that two of the openings cross the remaining openings and are positioned on opposite sides of each other.

At least one additional opening may be provided and the center of the additional opening or each additional opening lies on the pitch circle diameter defined by at least two of the first, second or third openings.

Only some of the openings may be of a splined shape and the remainder may have a flat side.

All openings may be of the splined type.

A position marker may be provided adjacent to the gear tooth row.

The position marker may be provided in the form of an arrow on the side wall of the gear tooth row.

The position marker may be provided as a through hole in a side wall of the gear tooth row.

A number or a number indicating the number may be provided on the gear wheel corresponding to the number of tooth teeth of the gear wheel.

Numbers or numbers may be provided adjacent each gear teeth array to form a series of numbers extending around the circumference of the gear wheel, or a letter representing a series of numbers.

The driving element may include a first elongate member and the first elongate member may extend through the opening or each opening and / or through the opening to be driveable with one side of the opening or each opening And is configured to rotate the first gear wheel about the rotation axis by engaging.

The first elongate member may have a length greater than the thickness of the first gear wheel element.

A crank arm may extend at an angle from the first elongate member.

The crank arm may be terminated in a second elongate member at an opposite end of the first elongate member of the crank arm.

The first elongate member may include a spline extending radially outwardly and configured to mesh with the opening of the first gearwheel element or the spline of each opening.

The second elongate member may be provided with a first recess having at least one spline and the at least one spline extends radially inward from an inner surface of the first recess.

Accordingly, there is provided a configurable toy that allows the configuration of a gear assembly that can be combined in various configurations and rotatable with a drive member, with the intention of educating the child about the characteristics, appearance, and feel of the gear system.

Several examples of the present disclosure will now be described with reference to the accompanying drawings.
1 is an upper side perspective view of a gear wheel element according to the present disclosure;
2 is a bottom side view of the gear wheel element shown in Fig.
3 is a top view of the gear wheel element shown in Figs. 1 and 2. Fig.
4 is a bottom side view of the gear wheel element shown in the preceding figure.
Figure 5 is a side view of the gear wheel element shown in the preceding figures.
6 is a top view of an alternative example of a gear wheel element in accordance with the present disclosure;
7 is a top perspective view of a further example of a gear wheel element in accordance with the present disclosure;
8 is a plan view of a further alternative example of the gearwheel element of FIG.
9 shows a further example of a gear wheel element according to the present disclosure.
10 is an upper side perspective view of a drive element according to the present disclosure;
11 is a bottom side view of the driving element shown in Fig.
12 is a top view of the driving element shown in Figs. 10 and 11. Fig.
Figure 13 is a bottom side view of the drive element shown in Figures 10-12.
Figure 14 is a side view of the drive element shown in Figures 10-13.
15 is a cross-sectional view of the driving element shown in Figs.
16 shows an example of an alternative design of a drive element for use in a configurable toy according to the present disclosure.
Figure 17 shows an example of a further alternative driving element that may be used with the presently constructed toys.
Figures 18-22 illustrate various combinations of gear wheels and drive / shaft elements of the presently constructed toys.
Figures 23A-E show additional examples of gear wheel elements in accordance with the present disclosure.
24A-E show further examples of a gear wheel element according to the present disclosure.
Figure 25 shows the combination of the gear wheel elements shown in Figures 23a-e and 24a-e.
Figure 26 shows the gear wheel element of Figure 25 in a different configuration.

Figures 1-26 illustrate an element of a configurable toy according to the present disclosure, which includes a plurality of pieces that can be assembled together to form various three-dimensional structures having rotatable elements. In other words, a structure that may be made using the toy elements of the present disclosure may include a rotatable portion. This rotatable portion may engage other rotatable portions to create a structure having a plurality of moving portions in use. Other rotatable portions may be similar to or different from the gear wheels of the present disclosure.

Features common to the various elements of this disclosure are identified using the same reference numerals.

The configurable toy includes a gear wheel element. 1 to 5 show an example of the first gearwheel element 10 according to the present disclosure. The gear wheel element 10 includes side walls 14 defining side and peripheral edges 16. A plurality of gear tooth rows 18 extend from the outer circumferential edge 16 of the first gearwheel element 10. In the illustrated example, there are ten gear tooth rows extending in the radial direction. Other gear tooth arrays may be provided and may be gear tooth arrays, for example, with teeth that extend at an angle (e.g., at right angles) to the side walls 14 and / or the main rotation axis of the gear wheel. The gear tooth row 18 is configured to operatively engage a second gear wheel element having a gear tooth row in a complementary shape to the gear tooth row 18 of the first gear wheel element.

The side wall 14 is provided with at least one opening. 1 to 5, the first gearwheel element 10 is shown as having three openings denoted by reference numerals 20, 22 and 24. These openings 20, 22, 24 have nominally the same diameter.

The openings 22, 24 differ from the openings 20 only in that they have a spline 26 extending radially inwardly towards the center. In other words, the openings 20, 24 have flat sides (i.e., are smooth and cylindrical) and the openings 22, 24 are in a splined form and thus interact with other ("male") spline- . In particular, the openings 20, 22, 24 are configured to receive a drive element in the form of a crank arm 100, described below with reference to Figs. 10-15, 18-22.

The smooth side opening is also configured to receive a portion of the driving element 100 at any location on the gear wheel and configured to be relatively rotatable relative to the driving element 100 with little or no frictional resistance.

Figures 16 and 17 illustrate the use of the present invention in conjunction with the crank arm 100 and gear wheel elements of the present disclosure for supporting and / or driving a gear wheel (i.e., a "drive element" Which is an example of the axles 200 and 202 that can be used. The axles 200 and 202 can extend through the spline-shaped opening of the gear wheel. The opening 20 in the smooth side of the gear wheel may also receive an elongated support member, for example an axle 200, 202, such that the first gearwheel element 10 about this axle likewise has no frictional resistance It can be rotated almost without.

The rotational axis through which the gear wheel 10 rotates may be aligned and / or coaxial with the central rotational axis 12 of the first gearwheel element 10. For example, the rotational axis may be defined by the openings 22, 24 (i.e., the openings 22, 24 offset from the central rotational axis 12) depending on which gear wheel is rotatably mounted on which opening ) Coaxial with the center of one).

In the example of Figures 1 to 5, the smooth side opening 20 is coaxial with the central rotation axis 12 of the first wheel element 10. The openings 22 and 24 are offset from the central rotation axis 12 of the first wheel element 10. The opening 22 is provided radially outwardly of the opening 20. The opening 24 is provided radially outwardly of the first opening 20. The centers of the openings 22 and 24 are spaced the same distance from the central rotational axis 12 to form a pitch circle diameter PCD centered on the central rotational axis 12. In other words, the centers of at least two of the openings are spaced the same distance from the axis of rotation to form a pitch circle diameter centered on the axis of rotation.

In the example of Figs. 1 to 5, the openings 20, 22 and 24 are aligned so that the openings 22 are located on the opposite sides of the openings 24 across the openings 20. In other words, two of the openings are located on opposite sides of the other openings.

Although three openings 20, 22 and 24 are shown in the example of Figures 1 to 5, the gear wheel element according to the present disclosure may be provided with one or two openings, or at least four openings.

6 shows an alternative example of the gearwheel element 10 '. The gearwheel element 10 'is identical to the gearwheel element 10 except that it has a spline extending radially inwardly in the central opening 20' just as the openings 22, 24 are spline-shaped. Do. In other words, the gearwheel element 10 'of Fig. 6 represents an example of a gearwheel element in which all openings of the gearwheel element are in a splined shape. The examples of Figures 1 to 5 show a gearwheel element 10 in which only a portion of the openings are of a splined shape and the remainder are flat sides.

FIG. 7 shows an alternative example of a gear wheel element 40 including 12 radially extending gear tooth rows 18. Since the gear teeth 18 of the gear wheel element 40 have substantially the same size and geometry as the gear wheel elements 10 and 10 ', the overall diameter of the gear wheel element 40 is greater than the overall diameter of the gear wheel elements 10, 10 '). The gear wheel element 40 includes a central aperture 20 centered on the central axis of rotation 12 of the gear wheel element 40. Although this central gearwheel opening 20 is shown as having a flat side, it may alternatively be of a splined shape. Which is surrounded by a plurality of openings 22, 24 centered on a common pitch circle diameter. Some of the openings are of the spline type, and some are not of the spline type (i.e., the flat side). The openings in the example of Figure 7 have diameters and dimensions that are nominally the same as the openings 20, 20 ', 22, 24 of the example of Figures 1-6. Therefore, the opening of the example of Fig. 7 is compatible with the same axles 200, 202 and crank arm 100 as the gear wheel example shown in Figs.

The example of Fig. 8 shows the same gear wheel element 40 'as the example shown in Fig. 7, except that there are different patterns of flat openings and splined openings. In the exemplary gear wheel element 40 shown in Fig. 7, three of the openings are of the splined type, and four of the openings have flat sides. In the example of Fig. 8, four of the openings are of the spline type, and three of the openings have a flat side surface. The examples of Figures 7 and 8 include more openings than the example of Figures 1-6. Additional openings 22, 24 are provided radially outwardly of the central opening 20 and the centers of the respective additional openings 22, 24 lie on a common pitch circle diameter. In other words, at least one additional opening is provided such that the center of each additional opening lies on the pitch circle diameter defined by the openings 22, 24.

The examples of Figs. 1 to 5 and Figs. 7 and 8 are examples of a gearwheel element in which only a part of the openings are of a splined shape and the remainder are flat. However, in other examples (e.g., in the example of FIG. 6) all of the passages may be of the spline type. For example, all of the passages in Figures 7 and 8 may be of the splined type.

9 shows an example of an additional gearwheel element 60 comprising fifteen gear tooth rows 18 extending radially outwardly. As a result, the overall diameter of the gearwheel element 60 is larger than the gearwheel of the preceding example. The gear wheel element 60 includes a central aperture 20 centered on the central axis of rotation 12 of the gear wheel element 60. Although this central gearwheel opening 20 is shown as having a flat side, it may alternatively be of a splined shape. Which is surrounded by a plurality of openings 22, 24 centered on a common pitch circle diameter. Although not required, the openings 22, 24 of the example of FIG. 9 are spaced apart and centered on the same PCD as the openings 22, 24 of the example of FIGS. Like the exemplary gearwheel 40, 40 'of FIGS. 7 and 8, only a portion of the openings are splined and the rest are flat. As an alternative example, both openings may be of the splined type. The number of splined openings may exceed the number of flat openings or may be less. Also, as a different example, the number of splined openings may be the same as the number of flat openings.

Each of the gear wheel elements 20, 20 ', 40, 40', 60 has a number 30 printed, embossed, or otherwise provided on the side wall 14 of the gear wheel element, Corresponds to the number of teeth teeth teeth 18 of this particular gearwheel element. This is to allow the child (or guardian of the child) to quickly identify the gear wheel required for use. Instead of a number, or a number, a letter representing a number, for example a spelled word, or a roman may be provided.

Each of the gear wheel elements 20, 20 ', 40, 40', 60 has a marker, for example arrow 32, as shown in Figures 1, 3, 6 and 9, and / And a through hole 33 provided adjacent to or adjacent to one of the gear tooth rows 18 as shown in Figs. This is to help the child observe the gear wheel rotation and help the relative rotation of the gear wheel when the gear wheels engage with each other.

In other words, the position marker may include an arrow 32 on one of the side teeth of gear tooth row 18. Additionally or alternatively, the position marker may include a through-hole 33 in the side wall of one of the gear tooth rows 18.

The openings 20, 22, 24 of the gearwheel may be provided either in the thin wall either alone or as a passageway or tube extending away from the wall 14 (as shown in the figure).

10-15 illustrate an example of a drive element 100 according to the present disclosure. The driving element 100 includes a first elongate member 102 configured to extend into and / or through each opening 20, 22, 24 of the gearwheel element. The elongate member 102 is also configured to operably engage the gearwheel through each splined opening to rotate the gearwheel element about an axis of rotation to provide a means for transmitting force to the gearwheel element. In other words, the drive element 100 can be driven (e.g., via the side of the opening and / or through the spline) through the openings 22, 24 to provide a means for transmitting force to the gearwheel element So as to rotate the gearwheel element about the axis of rotation.

The axis of rotation at which each gearwheel element is rotated may be the center axis 12 of the gearwheel element or may be connected to one of the remaining openings of the gearwheel element, It may be a centered rotation axis.

The first elongate member 102 of the drive element 100 may be configured to have a length greater than the thickness of at least one of the gearwheel elements of the present disclosure. The first elongate member 102 may also have a length less than the thickness of the gear wheel element of the present disclosure or may have a length approximately equal to the thickness of the gear wheel element into which this member extends.

A crank arm handle 104 is angled and extended from the first elongate member 102. In the illustrated example, the elongate member 102 extends at a substantially right angle from one side of the crank arm handle 104. The crank arm handle 104 is terminated at the second elongate member 106 at the opposite end of the first elongate member 102 of the crank arm handle 104. The second elongate member 106 extends at an angle from the crank arm handle 104. In the illustrated example, the second elongate member 106 extends at a generally right angle to the crank arm handle 104. The first elongate member 102 extends from the side of the crank arm handle 104 that is different from the second elongate member 106. The first elongate member 102 extends from the crank arm handle 104 in a first direction and the second elongate member 104 extends from the crank arm handle 104 in a second direction. The first direction may be opposite to the second direction. The first direction may be at a predetermined angle with the second direction.

The first elongate member 102 includes a spline 108 extending radially outwardly and configured to engage a spline 26 of each opening 20, 22, 24 of the gearwheel element.

The second elongate member 106 is provided with a first recess 110 having at least one spline 112 that extends from the inner surface 114 of the first recess 110, As shown in Fig. The first recess 110 may extend completely through the second elongate member 106 such that the second elongate member 106 is open at both ends.

The first recess 110 (i.e., the "female" portion) of the crank drive arm 100 has a nominal diameter and dimension equal to the openings 20, 20 ', 22 and 24 of the gearwheel. Likewise, the splines 112 of the crank drive arm 100 have the same shape and size as the splines 26 of the openings 20, 22 and 24. The axles 200 and 202 thus extend through the recesses 110 provided in the crank arm 100 to allow the recesses 110 and the recesses 110 provided in the crank arm 100, 110). The splined extension member 102 of the drive arm 100 also enters into the recess 110 and is configured to mate with it. The drive arm 100 is engaged by causing the first elongated member 104 of one drive crank arm element 100 to slide into the second elongate member 106 of the other drive crank arm element 100 Thereby increasing the crank arm length and providing a larger lever.

Figures 18-22 illustrate an exemplary assembly of the gear wheel and axle / drive element 100, 200, 202 of the present disclosure. The combination of elements shown is by no means intended to be limiting, but merely as an example of how the elements of the presently constructed toy can be assembled and utilized.

18 shows an assembly of elements of a configurable toy of the present disclosure including a first gearwheel element 60 supported on an axle member 202. Fig. And a second gear wheel element 10 supported on the axle member 202 is positioned beside it. The two gear wheel elements 10 and 60 are rotatable about the axle member 202. The axle member 202 extends through a gear wheel element into a support structure (not shown) behind the gear wheel elements 10, 60. The center opening 20 of the first and second gearwheel elements 60 and 10 is flat so that the gearwheel elements 60 and 10 can rotate freely around each axle 202. [

The crank arm drive element 100 engages the splined opening 24 on the larger gear wheel element 60. The gear wheel element 60 is engaged with the spline of the crank arm drive element 100 so that when the user applies a force on the drive element 100 the gear wheel element 60 is rotated about the center axis 12 of the opening 20 60 will rotate causing the gear wheel element 60 to rotate about its central axis 12. As the gear wheels are adjacent to each other and their gear teeth 18 are operatively engaged with each other, rotation of the first gearwheel element 60 will cause the second gearwheel element 10 to rotate.

The driving element 100 is engaged with the spline-shaped opening 24 by sliding into the spline-shaped opening 24 of the gearwheel element using the splines of the first elongate member 102 in a state of misalignment with the opening spline Whereby the rotation of the crank arm 100 engages with the spline 26 of the opening when the elongated member 102 of the crank arm 100 is at least partially engaged into the opening so that the force applied to the driving element 100 May be applied directly to the splines 26 and thereby applied to the gear wheel.

Fig. 19 shows a configuration slightly different from that shown in Fig. In this configuration, the driving elements 100 are oriented at different angles with respect to the openings 24 to which the driving elements 100 are engaged.

Figure 20 shows that the small gearwheel 10 'described with reference to Figure 6 is provided next to the large gearwheel 60 and the small gearwheel 10' has three splined openings in the sidewall 14 18 < / RTI > and 19, except for the fact that < RTI ID = 0.0 > In this example, the axle 200 extends from the same central opening 20 'from which the crank arm 100 extends, wherein the axle extends into the support structure behind the gearwheel element 10' and freely rotates therein . The gear wheel element 10 'is positioned adjacent to the larger gear wheel element 60 such that the gear tooth row 18 engages with the gear teeth of the gear wheel 60. In this configuration, the user rotates the crank arm 100 to rotate the gear wheel 10 ', which in turn rotates the gear wheel 60.

The configuration of Figure 21 is similar to that of Figure 21 except that the crank arm 100 is located in the opening 22 offset from the central opening 20 of the gearwheel element 10 having the smooth, 20 are substantially the same as those shown in Figs. Therefore, when a force is applied to the crank arm 100, the gearwheel element 10 is rotated, and the gearwheel element 60 is thereby rotated.

Figure 22 shows a further example of an assembly made possible by the toy elements of the present disclosure.

The support structure 302 serves as a base for the first gear wheel 300. In this example, the support structure 302 comprises a toy brick having a plurality of flat side openings 306 having shapes and sizes complementary to the axles 200, 202 and the crank arm 100. The first gear wheel 300 has a single spline-shaped opening 22 coaxial with the central axis of rotation. The drive element provided to the axle 200 extends through the opening 306 of the support structure 302 and through the splined opening 22 of the first gearwheel 300 and extends through the side wall of the gearwheel 300 14). The driving element 100 provided with the crank arm is fitted to the end of the axle driving element 200. The drive elements therefore comprise a crank arm (100) and an axle (200) which are operatively engaged with each other. The axle 200 is operatively engaged with the gear wheel 300 and the drive elements (i.e., the crank arm 100 and the axle 200) are rotatable relative to the support structure 302.

The second gear wheel 40 is supported on the axle 202 and is mounted to the first gear wheel 300 such that the teeth 18 of the first gear wheel 300 are engaged with the teeth of the second gear wheel element 18, respectively. The axle 202 extends through the support structure 302 through the central opening 20 of the planar side of the gear wheel 40. The stop portion 304 is pushed onto the end of the shaft 202 to prevent it from retracting from the support structure 302 and the shaft 202 is moved relative to the support structure 302 relative to the gear wheel 40 It is rotatable together. Accordingly, the user can rotate the crank arm driving element 100, and the crank arm driving element 100 is engaged with the axle driving element to transmit the force, and this axle driving element is engaged with the first gear wheel 300, So that the gear wheel 40 is rotated.

Of course, numerous combinations can be developed that allow the user to explore the various features of the gear system, respectively. With each configuration, the user is able to explore not only the various properties of the gear system but also the concepts of torque, leverage and friction.

Figures 23A-E and 24A-E show additional examples of the gear wheel elements 400, 500 according to the present disclosure, each having five gear tooth rows 18 and fifteen gear tooth rows 18, respectively. Other elements of similar design may be provided having six, eight, ten, twelve, or sixteen gear teeth 18.

In most major respects, the gear wheel elements 400, 500 of Figures 23a-e, 24a-e are the same as those of Figures 1-9. The gear tooth row 18 is slightly elongated. The arrangement of the flat and splined openings 20, 22, 24 can be provided for the same reason with the same configuration as described above.

A number 402 or a number 402 adjacent the respective gear tooth row 18 to form a series of numbers 402 extending around the circumference of the gear wheels 400 and 500 or letters representing a series of numbers 402, A character indicating the character 402 may be provided. In other words, each gear tooth row 18 is denoted by a number indicator 402. Instead of a number, or a number, a letter representing a number, for example a spelled word, or a roman may be provided. The value of the number 402 may vary by a value of 1 per gear tooth row 18. Thus, proceeding clockwise or counterclockwise around the gear tooth array 18, the numbers may range from one (1) to the number of teeth on the gear wheel elements, for example five (5), six (6), eight ), Ten (10), twelve (12), fifteen (15), or sixteen (16). The number permutation can be increased clockwise or counterclockwise. The number 402 may be printed, embossed, or otherwise provided on the side walls 14 of the gear wheels 400, 500.

Figure 25 shows the combination of the gear wheel elements 400, 500 shown in Figures 23a-e and 24a-e. Both of which are rotatably mounted about their respective central rotation shafts 12. Therefore, the rotation of the small gear wheel 400 will cause the large gear wheel 500 to rotate. Likewise, other elements of the same configuration, for example, other elements having different numbers of gear tooth rows 18, may be assembled to form a three-dimensional rotatable structure.

This is especially useful when teaching your child about addition. Consider the relative orientation of the gear wheels 400 and 500 in a state in which the gear tooth rows "1" of the respective gear wheels are in contact with each other in Fig. The clockwise rotation of the small gear wheel 400 will cause the large gear wheel 500 to rotate in the counterclockwise direction. It can be noted that such a rotation of the small gearwheel 400 causes the two gear teeth 18 of the small gearwheel 400 to rotate the larger gearwheel 500 by the same number of gear teeth 18 positions So that the teeth can be engaged in the teeth number "3" of the large gear wheel 500. Thus, "1" plus "2" will easily illustrate that it is "3". Likewise, other calculations and observations relating to the relative rotation of the two wheels 400, 500 are easily identified and recorded due to gear number 402.

Although numbers / letters 402 are shown as being provided on the gearwheel elements 400, 500 of FIGS. 23A-E, 24A-E, these numbers / letters are shown on the gearwheel elements shown in FIGS. , And on a gear wheel element similar to the design shown in Figures 1-9.

Thus, there is provided a configurable toy comprising a plurality of elements, each of which can be rotated together to form a variety of three-dimensional structures using rotatable elements, which may be rotated and dependent on each other Can be assembled. In other words, the rotatable gear wheels can be assembled relative to each other and mounted to rotate relative to each other and / or to each other. The drive element 100 provides a means for powering the gear wheel system that is made.

Thus, a plurality of configurations can be created and tested by the user. Due to the flexibility of the system, an unstructured creative play as well as an induced training session is made possible, which leads to causal relationships, friction, torque, and therefore the best and worst configurations for these gear systems, The child will be able to support learning.

It should be noted that all documents and documents filed concurrently with this specification and filed with the present specification and published with the present specification in connection with the present application and the contents of such documents and documents are incorporated herein by reference.

All features disclosed in this specification (including any accompanying claims, abstract, and drawings) and / or any steps of any method or process disclosed herein are to be construed as including, without limitation, except where such features and / or steps are mutually exclusive May be combined in any combination.

Each feature disclosed in this specification (including any accompanying claims, abstract, and drawings) may be replaced by alternative features that perform the same, equivalent, or similar purposes, unless expressly stated otherwise . Thus, unless expressly stated otherwise, each feature disclosed is but one example of a comprehensive set of equivalent or similar features.

The present invention is not limited to the details of the preceding embodiments. The invention is not limited to any novel or any novel combination of features disclosed in this specification (including any accompanying claims, abstract and drawings), or any novel one of the steps of any disclosed method or process , Or any new combination.

Claims (13)

A configurable toy comprising a plurality of elements (10, 40, 40 ', 60, 100, 200, 202, 300, 302, 304, 400, 500)
The plurality of elements may be assembled together to form various three-dimensional rotatable structures, the elements including first gear wheel elements (10, 40, 40 ', 60, 400, 500) The wheel elements are:
A side wall (14) defining a side surface of the first gear wheel element and a peripheral edge (16) of the first gear wheel element;
A plurality of gear tooth rows (18) around an outer circumferential edge of the first gear wheel element, the second gear wheel elements (10, 40, 40 ') having a gear tooth row in a shape complementary to the gear tooth row of the first gear wheel element , ≪ / RTI > 60, 400, 500);
A first opening (20, 20 ', 22, 24) provided on the sidewall and configured to receive a driving element (100), the driving element (100) Wherein the first gear wheel is rotatable about an axis of rotation that is aligned or coaxial with the center axis of rotation of the first gear wheel by operatively engaging the gear wheel through the aperture to provide a means for transmitting An opening;
A second opening (22, 24) provided offset from the first opening; And
And a third opening (22, 24) provided offset from the first opening and the second opening,
Only a part of the openings is a spline type 26 and the rest is flat type,
Wherein the drive element comprises a first elongate member and the first elongate member extends through the orifice and / or the opening of each of the openings (20, 20 ', 22, 24) 40, 40 ', 60, 400, 500 around the axis of rotation 12 by engaging the openings 20, 20', 22, 24 or one side of each of the openings, To rotate,
A crank arm (104) extends at an angle from said first elongate member, said crank arm terminating in a second elongate member (106) at an opposite end of said first elongate member of said crank arm,
The second elongate member 106 is provided with a first recess 110 having at least one spline 112 and the at least one spline 112 extends radially inward from the inner surface of the first recess Wherein the at least one element comprises a plurality of elements. The method according to claim 1,
Wherein the first opening is offset from a central rotational axis of the first gear wheel (10, 40, 40 ', 60, 400, 500). The method according to claim 1,
Wherein the first opening 20,20'includes a plurality of elements coaxial with the central axis of rotation 12 of the first gearwheel 10,40,40'60, Type toy. 4. The method according to any one of claims 1 to 3,
At least two of the openings 22 and 24 are spaced a same distance from the axis of rotation 12 to form a pitch circle diameter centered on the axis of rotation 12, A configurable toy comprising an element. 5. The method of claim 4,
The first, second and third openings 20, 22 and 24 comprise a plurality of elements arranged such that two of the openings 22 and 24 are located opposite to each other across the remaining openings 20 Toys. 6. The method according to any one of claims 1 to 5,
Wherein at least one additional opening (22, 24) is provided and wherein the center of the additional opening (22, 24) or each additional opening is at least two of the first, second or third openings And a plurality of elements lying on the pitch circle diameter defined by the dog. 7. The method according to any one of claims 1 to 6,
Wherein the position marker (32, 33) is provided adjacent the gear teeth row (18). 8. The method of claim 7,
Wherein the position marker comprises a plurality of elements, including an arrow (32) on a sidewall of the gear tooth array (18). 8. The method of claim 7,
Wherein the position marker comprises a plurality of elements including a through hole (33) in a side wall of the gear tooth array (18). 10. The method according to any one of claims 1 to 9,
(30) on the gear wheels (10, 40, 40 ', 60, 400, 500) corresponding to the number of teeth teeth teeth (18) of the gear wheels (10, 40, 40' ), Or a number indicating the number is provided. 11. The method according to any one of claims 1 to 10,
Adjacent to each gear teeth array (18) to form a series of numbers extending around the circumference of the gear wheel (10, 40, 40 ', 60, 400, 500) 402), or a number indicating the number is provided. 12. The method according to any one of claims 1 to 11,
Wherein the first elongate member (102) comprises a plurality of elements having a length greater than the thickness of the first gear wheel element (10, 40, 40 ', 60, 400, 500). 13. The method according to any one of claims 1 to 12,
The first elongate member 102 extends radially outwardly and extends through the openings 20, 20 ', 22, 24 of the first gearwheel element 10, 40, 40', 60, Or a spline (108) configured to mate with a spline (26) of each opening.

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