The present invention is an amusement device concerned generally with a construction type educational toy. The apparatus disclosed provides unique functionality via board design and piece structure allowing relative motion between coupled playing pieces. The construction apparatus is of the type having rotary path-forming pieces that can be located in numerous positions on the base board. The pieces are removably interfitting and allow the construction of variable paths and patterns.
The amusement device incorporates magnetism to perform relative rotary motion. A circular pattern of permanent magnets are included in construction pieces to allow numerous magnetically coupled rotary pieces to undergo relative rotation analogous to a gear train. In addition to toy or game amusement device, the present invention also embodies an education and demonstration device whereby the assembly of magnetically coupled rotary pieces provides the interactive demonstration of a gear train machine mechanism.
A variety of amusement devices exist having parts assembled for relative movement including rotary gears, pulleys, or strand-winding members such as those found in United States Patent Class 446, Subclass 112 and having permanent magnets in United States Patent Class 446, Subclass 129. Likewise, other amusement devices exist as games in United States Patent Class 273 including, but not limited to, Subclasses 239, 275, 276, 282.1, 284, 287, and 288. Still further, a variety of related machine mechanisms exist for education and demonstration having means for demonstrating apparatus, product, or surface configuration, or for displaying education material or student's work such as those found in United States Patent Class 434, Subclass 401.
It is an object of the present invention to obviate or mitigate at least one disadvantage of previous amusement devices.
In a first aspect, the present invention provides a construction set including: a plurality of magnetized rotary construction pieces and a journal board adapted for receiving the magnetized rotary construction pieces within a playing area of numerous closely-spaced receptacle pivot locations; the magnetized rotary construction pieces each including a body portion and a centralized axle projection; the axle projection adapted to removably-fit on the journal board and rotate within the receptacle pivot locations of the journal board; the body portion further including magnetized elements arranged in a circular pattern with numerous locations of outward magnetic polarity around the periphery of the rotary construction pieces; and magnetized elements adapted for providing for rotational magnetic coupling when the magnetized rotary construction pieces are placed in proximity to each other on the journal board.
In further aspect, the present invention provides a construction set including; a magnetized drive ring, a plurality of magnetized rotary construction pieces and a journal board including a journal array adapted for receiving the magnetized rotary construction pieces within a playing area of numerous receptacle pivot locations; the journal board further including a substantially annular ring supporting means adapted for providing the pivoting of the magnetized drive ring around the periphery of the journal hole array; the magnetized rotary construction pieces each including a body portion and a centralized axle; the axle adapted to removably-fit on the journal board and rotate within the receptacle pivot locations of the journal board; the body portion further including a circular pattern of magnetized elements adapted for rotational magnetic coupling when the magnetized rotary construction pieces are closely spaced apart on the journal board; the magnetized drive ring including a ring-shaped body characterized by a major and minor diameter and a rotation drive means; the magnetized drive ring adapted to be rotationally supported by the annular ring supporting means of the journal board; and the ring-shaped body including a circular pattern of magnetized elements positioned near the minor diameter and adapted to provide rotational magnetic coupling when the magnetized rotary construction pieces are placed on the journal board within the magnetized drive ring in proximity to the minor diameter of the magnetized drive ring.
Generally speaking, the present invention is an amusement device concerned with a construction toy system of high educational value. The construction type apparatus disclosed provides unique capability for amusement via board design and playing piece structure allowing relative motion between playing pieces. The apparatus is of the type having rotary path-forming playing pieces that can be located in numerous positions on a journal board. Moreover, the playing pieces are removably interfitting and allow the construction of variable paths and design patterns.
The amusement device incorporates magnetism to perform relative rotary motion. A circular pattern of permanent magnets are included in playing pieces to allow numerous magnetically coupled rotary pieces to undergo relative rotation analogous to a gear train.
The invention has multiple formats and applications. A preferred format is a construction system in which a person can employ the playing pieces in numerous patterns and configurations for achieving complete magnetic coupling and simultaneous motion.
An individual may explore numbers patterns and configurations of magnetically coupled rotary playing pieces as curiosity directs in “solitare” play. As playing pieces are removably interfitting with the game board, the rotating disks can be arranged and re-arranged with substantial freedom to form theories and investigate results of pattern formation. For example the device allows the construction of circular patterns, linear patterns, spiral patterns, and patterns which are symmetrical about one or more planes. Depending on placement and configuration the invention allows an individual to also form closed loops where as more than one playing piece of the same “gear train” is linked to the lead gear.
As the invention allows simultaneous motion of a multitude of disks, dynamic visual results can be achieved with greater expression through the deployment of graphical cover plates. These covers can be added and exchanged based on the user's opinion. The plastic cover plates add an extra layer of creative construction and play since the interchanging graphics can give a single pattern a different look and feel and thus a higher level of versatility and personalization is enjoyed in the contest of the construction system.
According to a secondary format, the construction system can be adapted for competitive playing by a number of individuals. In competitive play, players take turns adding rotary playing piece until free space on the board is diminished to the point where adding additional pieces disrupts the magnetic coupling of previously placed rotary pieces. According to this competitive format, the path forming game of this type relies on mental processes and strategy to construct a pattern in maximizing the number of magnetically coupled rotary playing pieces as part of the “gear train”.
In all conceived playing formats, successful execution will depend on mental process such as knowledge of combinations relative to interchangeable gears and being able to visually estimate transverse and diagonal distances between placement locations. Successful placement also depends on an awareness on how distance between playing pieces relates to the magnitude of constructive coupling or interference depending on the properties of the playing pieces such as size and pattern of permanent magnets displaced on rotary playing pieces.
Competitive game play according to the present invention does also enable the use of strategy for proactive placement or rotary playing pieces in the attempt to limit the selection of pivot locations of an opposing opponent and force the outcome of an opponent causing the “gear train” to “lock up” on account of poor placement or limited placement options. Thus it will be come apparent to one skilled in the art that the novel construction system provides an interactive apparatus for exploring the principles of magnetic coupling and relative motion. Such an interactive apparatus is so adapted to be both enjoyable and intellectually stimulating.
In addition providing amusement and various formats for play, the present invention also embodies an education and demonstration device whereby the assembly of magnetically coupled rotary pieces provides the interactive demonstration of a gear train machine mechanism
The invention enables a high degree of interchangeable, variable, or plural distinct playing patterns via the substantially dense array of pivot locations provided for within the journal board array. The closely spaced array of receiving holes enables relatively precise positioning of playing pieces to build an assembly that exhibits relative movement of all magnetically coupled playing pieces via rotation of single driving disk or ring.
Several embodiments are disclosed including a first preferred embodiment in a system designed around a journal board in which a driving disk shaped crank is centrally located. According to this embodiment, playing pieces are placed to extend the “gear train” of magnetically coupled rotary playing pieces such as to provide an “inside-out” playing format.
Other preferred embodiments include those wherein the journal board is circular and a rotational-magnetic ring crank is located to revolve around the outside of the array of journal positions. According to this preferred embodiment, playing pieces are added to extend the “gear train” from the inside of the ring toward the center of the journal hole array such as to provide an “outside-in” playing format. The exterior ring crank comprises a revolving handle which allows easy revolution according to the manipulation of the user.
An added benefit of this preferred configuration, in comparison to other configurations utilizing a central driving gear is that the players can drive the rotary playing pieces to spin at higher speeds enabling them to explore a wider range of visual and magnetic interactive effects with greater ability to alter the dynamics. For example, relative motion between rotary playing pieces caused by magnetic coupling can be overcome by suddenly switching the direction of rotation and rotating at high speed. One or more playing pieces that would normally spin when rotating the driving member at low speed can be caused not to spin at high speed by dynamic manipulation. Furthermore, a player can strategize about the placement of rotary playing pieces such that intended dynamic effects can be deliberately achieved.
To summarize, the construction system according to the present invention is characterized with the following advantages.
The construction system is fun and enjoyable to play and use.
The construction system is intriguing in that it allows a large number of non-touching rotary playing pieces to be magnetically coupled so as rotation of one rotary playing piece causes a great many of other playing pieces to also rotate.
The construction system is highly interactive and allows many variable paths and patterns.
The construction system is visually pleasing and allows one to see the effects of applying customizable graphics to simultaneously spinning playing pieces.
The construction system instructs players of the principles of magnetic coupling and interaction and how variables act to encourage and discourage the rotational coupling.
The construction system instructs players of relative rotary motion analogous to gear trains.
The construction system encourages spatial intelligence in the strategic placement of rotary playing pieces.
The amusement device provides a novel format of play whereas magnetic properties of rotary playing pieces work both productively and counter-productively in the progress of play.
The construction system allows an individual to explore and investigate numerous patterns and configurations as curiosity leads.
The construction system is novel and intriguing in how it allows one to visualize magnetic interaction in a dynamic format.
The construction system is “hands on” in that one can touch and feel the results of configuring and reconfiguring the magnetically coupled apparatus.
Other advantages and benefits may be possible, and it is not necessary to achieve all or any of these benefits or advantages in order to practice the invention as claimed. Therefore, nothing in the forgoing description of the possible or exemplary advantages and benefits can or should be taken as limiting.
The novel features of the present invention, which are considered as characteristic for the invention, are set forth with particularity in the appended claims. The invention itself, however, both as to organization and methods of operation, together with further objects and advantages thereof, may best be understood by reference to the following description, taken in conjunction with the accompanying drawings in which:
As utilized herein, terms such as “about”, “approximately”, “substantially” and “near” are intended to allow some leeway in mathematical exactness to account for tolerances that are acceptable in the trade.
Before explaining the present invention in detail, it should be noted that the invention is not limited in its application or use to the details of construction and arrangement of parts illustrated in the accompanying drawings and description. The illustrative embodiments of the invention may be implemented or incorporated in other embodiment, variations and modifications, and may be practices or carried out in various ways. Furthermore, unless otherwise indicated, the terms and expressions employed herein have been chosen for the purpose of describing the illustrative embodiments of the present invention for the convenience of the reader and are not for the purpose of limiting the invention. Further it is understood that any one or more of the following-described embodiments, expressions of embodiments, examples, methods, etc. Can be combined with any one or more of the other following-described embodiments, expressions or embodiments, examples, methods, etc.
Referring to
The base of the apparatus is journal board 110 adapted to receive rotational-magnetic playing pieces 61. Each large, medium and small rotational-magnetic playing pieces 62A, 62B, and 62C comprises a substantially circular disk body 64A, B and C. Handle portion 65A, B and C is a slender projection extend above respective disk bodies for facilitating hand placement on journal base board. Each of the rotational-magnetic playing pieces further comprise shafts portion 66A, B and C respectively centrally projecting below disk bodies 64A, B, and C and are adapted to closely fit within variable journal positions of journal hole array 112 of journal board 110.
Playing pieces are further provided with graphical cover plates 80E, 81E, and 82E adapted to fit on magnetic-rotational playing pieces over handle portions 65A, 65B and 65C respectively.
Journal board 110 comprises journal grid 112 which is an array of holes of sufficient depth to receive shaft portions 66A, B and C of rotational-magnetic playing pieces 62A, B and C. Accordingly, playing pieces 62A, B, and C slip into journal board 110 and are permitted to pivot in numerous pivot locations as provided by journal hole array 112 having a grid comprising a hole pattern. Journal hole array 112 is of sufficient size and hole density to allow numerous pivot locations for rotational-magnetic playing piece 62A, B, and C to be placed in close proximity on journal board 110 such that disk portions 64A, B, and C reside on top surface 114 of journal board 110 without touching each other while also freely pivoting on axis of each respective shaft portion 66A, B, and C. Preferably journal board 110 is made of a low friction plastic material such as Acetal copolymer or PVDF. Another preferred low friction yet dimensionally stable material would be Delrin impregnated with Teflon.
Holes of journal hole array is preferably of maximum area and density for allowing the maximum number of pivot locations within area of journal hole array 112. Accordingly, the preferred spacing between holes is less than 1.5 times the hole diameters. Journal base board 110 is of sufficient thickness to support rotational-magnetic playing piece in magnetically coupled configurations without yielding under the action of magnetically attractive and repulsive forces.
Rotational-magnetic disk crank 74 is provided with revolving handle 75 projecting from the top of disk portion 64 and located near the edge of disk portion 64 for enabling crank operation in initiating rotation of magnetically coupled rotational-magnetic playing pieces 64A, B and C. Preferably, rotational-magnetic disk crank comprises disk portion 64 of larger size than rotational-magnetic playing pieces 61, whereas the larger size helps facilitate the cranking action and enables a larger number of rotational-magnetic playing pieces to be magnetically coupled directly to disk crank 74.
Shown in
Now referring to
Shaft portion 66C and handle portion 65C are integral to disk body 64C where as they are all part of a single injection molded component to which rectangular magnets are subsequently installed. Although shaft portion is of a small diameter the required length is sufficiently small to prevent it from being easily damaged a result of applied bending loads. This provides a cost advantage with the ability to mass produce the rotational-magnetic playing pieces with minimum additional material costs other than the costs of the embedded rectangular magnets 69. Alternatively the shaft portion 66C may consist of a metal pin pressed into disk portion 64C. Such a shaft could provide reduced friction and increased stiffness to shaft portion 66C. Above shaft portion 66C disk portion 64C further comprises contoured bottom 71C for reducing the contacting surface area with the journal base board 110 when placed thereon whereas the surface area of bearing surface 72C is much less than the surface area corresponding to contoured bottom 71C.
Disk body 64C further comprises axial slots 68C in which rectangular magnets 69 are housed. Axial slots 68C are arranged in a circular pattern within disk body 64C for accommodating rectangular magnets 69 in a circular pattern near disk parameter 74C. When pressed into axial slots 68C, rectangular magnets 69 are substantially embedded in disk body. Slot recesses 70C remain when the rectangular magnets are fully inserted during manufacturing and can be subsequently filled with adhesive or an interlocking cap so that magnets 69 are completely encapsulated within disk body 64C. However a light interference fit is all that is needed for preventing rectangular magnets 69 from being able to be dislodged from disk body 64C when under magnetic attractive and repulsive loading. Alternatively, rectangular magnets 69 are over molded during manufacturing to provide full encapsulation.
As shown in the sectional view of
According to this preferred embodiment, centralized handle portion 65C is substantially slender, is sufficiently long to be gripped by hand for easy placement, and is of an oblong cross section. The slenderness of handle portion 65C enables graphical cover plate 82E to be of maximum surface area and the oblong shape facilitates interlocking with central oblong hole 83C of cover piece 82E so that when cover plate 82E is placed on rotational-magnetic playing piece 62C it spins in conjunction with small rotational-magnetic playing piece 62C.
Small graphical cover plate 82E is preferably a removable substrate that can be placed upon rotational-magnetic playing piece 62C or can be exchanged for graphical cover plates of the same size having alternate graphics. For example Small graphical cover plate 85E could be a stamped from a plastic sheet and provided with an adhesive graphics. Alternatively graphical cover plate 82E may comprise a substrate suitable for painted or printed graphics applied directly thereto. Another alternative is for graphical cover plate to a cardboard cutout supplied with the construction set whereas differing supplied cardboard graphical cover plates can be selected from punch-out cardboard sheets of profiles and graphical indication means similar to the various graphical cover plates shown in
Graphical cover plate 82E is characterized as a thin disk with outside diameter 84C and a central oblong hole 83C. Outside diameter 84C is substantially equivalent to diameter associated with disk parameter 73C. Graphics 89E are displaced on top face 85C and optionally also on bottom face 86C. For example, a clockwise spiral graphic similar to that shown may be on the top face while the bottom face may contain a counter-clockwise spiral so that playing pieces may be configured so that you get the same dynamic visual effect for playing pieces rotating both clockwise and counterclockwise.
Now referring to
Also similar to small rotational-magnetic playing piece 62C, centralized handle portion 65A is substantially slender and of an oblong cross-section. This enables graphical cover plate 80E to be of maximum surface area and the oblong shape facilitates interlocking with central oblong hole 83A of cover piece 80E so that, when cover plate 80E is placed on rotational-magnetic playing piece 62A, it spins in conjunction with large rotational-magnetic playing piece 62A.
Now referring to
Revolving handle 75 comprises handle base 76 affixed to disk body 64. Handle sleeve 78 is retained on outside of handle base 76 and is adapted to freely rotate thereon so that a person may freely apply a cranking action to rotational-magnetic disk crank 74 whereas magnetic interaction between rotary playing pieces and inertia of playing pieces are the significant counteracting forces when initiating rotation of playing pieces.
Rotational-magnetic disk crank 74 further comprises contoured bottom 71 for providing a bearing surface 72 of minimal yet adequate surface area for contacting journal board when shaft portion 66 is inserted into a pivot location within journal array 112.
Graphical indication means is located on top surface 67 of disk body 64 and preferably includes visual indication means to indicate polarity of internal rectangular magnets embedded within. Preferably graphical indication is provided by an adhesive decal or is printed directly on the substrate that comprises disk portion 64.
Similar to the preferred embodiment of playing pieces 62A, B, and C, disk portion 64 of rotational-magnetic disk crank 74 comprises axial slots 68 for embedding rectangular magnets 69. Preferably, subsequent to insertion of rectangular magnets 69, the slot recesses 70 would be filled with adhesive or sealed in some other manner known to those skilled in the art.
As shown in
It should be understood that the rotary playing pieces may be injection molded parts adapted to receive rectangular magnets 69. Preferably, strong rare earth NdFeB permanent magnets are utilized which are composed mainly of Neodymium (Nd), Iron (Fe) and Boron (B). Although parameters 73A, B, and C are shown as round the actual shape of disk body 64A, B and C may be a polygon or another non-circular shape within the scope of the invention. Moreover, the magnets may be other than the rectangular magnets 69 as shown.
Although according the preferred embodiment shown magnetized elements are discrete magnets (i.e., rectangular magnets 69) displaced in axial slots in circular configuration arranged to provide alternating outward polarity, it should be readily understood as within the scope of the invention that magnetization can alternatively be provided by magnetic strip wrapped around the parameter of disk bodies adapted for providing substantially equivalent functionality. It is know to those practiced in the art that multi-pole magnetic strip can be manufactured with a specified width, thickness and length whereas the magnetic strip exhibits a fixed number evenly distributed number of magnetic poles per unit length. For example, according to the invention, magnetic strip that is 0.100 inch thick, 0.250 inch wide and has four poles per inch can be utilized for providing substantially equivalent performance.
Although magnetized elements according to an embodiment utilizing magnetic strip might require a greater volume of magnetic material to provide an equivalent magnetic field whereas a greater width or thickness as compared as to discrete magnets would be required, magnetic strip would provide a cost savings to the extent that cost attributed to magnetic strip as the magnetized elements would be ⅕ to 1/10 the associated costs of using discrete magnets.
In addition to cost savings pertaining to the magnetic material, magnetic strip would also provide improved manufacturability of the device components as compared to utilizing costly discrete magnets which much be precisely accommodated within slots in disk bodies. According to an alternative embodiment utilizing magnetic strip as the magnetization means, the strip can be wrapped around and secured to disk bodies with the use of adhesive and preferably with additional means of securing the strip such as providing for a two-part disk body having a plug and socket type interface for fully encasing the magnetic strip. Such a configuration would likely be characterized with increased product safety.
Referring to
Referring to
Circular magnetic pitch P74 of rotational-magnetic disk crank 74 and circular pitch P62C of rotational-magnetic playing piece 62C are substantially equivalent according to the invention as needed for effective coupling between various sized playing pieces. Thus all rotational-magnetic construction pieces including disk crank 74 and large, medium and small rotational-magnetic construction pieces 62A, B, and C have a substantially equivalent circular pitch for providing interchangeability whereas all rotational-magnetic construction pieces can be effectively coupled together.
In this preferred embodiment, variables associated with magnetic coupling are pitch diameters D74D and D62D working depth Dw and pitch point P. Magnetic coupling allows these variables to change depending on proximity of one playing piece to another. This a principal advantage of the invention as compared to other rotational construction type systems relying on mechanical interlocking such as those involving toothed mechanical gears.
According to the invention, Dw can be very small or very large and still provide magnetic coupling between rotational-magnetic disk crank 74 and rotational-magnetic playing piece 62C. However as working depth Dw increases as a result of further apart spacing, the strength of magnetic coupling decreases. The maximum working depth Dw is also influenced by the proximity of other nearby rotational-magnetic playing pieces. This variable is important in constructing various configurations and patterns because proximity can encourage magnetic coupling or cause counter-productive interaction. Thus strategy and intuition is required for achieving relative motion of all rotary construction pieces together such that when rotational-magnetic disk crank is cranked all other rotational-magnetic playing piece 62A, B and C also spin.
Referring to
Although rotational-magnetic playing pieces do not physically touch each other when placed in proximity on journal board array 112 the invention utilizes magnetic coupling such that manual rotation of one rotational-magnetic disk crank 74 will cause all magnetically coupled playing pieces 62A, B and C to rotate. Several parameters influence magnetic coupling and the ability to build a path of closely placed rotational-magnetic playing piece 62A, B and C wherein all rotate in response to the manual rotation of a rotational-magnetic disk crank 74. These parameters include but are not limited to differences in radial pitch and size and distance between placed playing pieces.
As indicated by shading of graphical cover plates shown in
Although shown in a straight line, numerous configurations of magnetically coupled rotary construction pieces are possible by strategic placement of playing pieces 62A, B and C within journal hole array 112. Although rotational-magnetic playing piece 62A, B and C vary in size and number of radial magnets 69 each rotational-magnetic playing piece 62A, B and C comprises a circular pattern of an even number of spaced apart rectangular magnets 69 that are characterized with a substantially equivalent radial spacing. Thus large rotational-magnetic playing piece 62A, medium rotational-magnetic playing piece 62B and small rotational-magnetic playing piece 62C are each characterized with a radial pitch within an acceptable range to facilitate effective magnetic coupling.
The size of each disk portion corresponding to the various sized rotational-magnetic playing pieces 62A, B and C is preferably determined according to a numerical relationship corresponding to the spacing between pivot point locations along journal hole array 112. For example, according to the preferred embodiment of
According to the invention, when journal hole array 112 is populated with rotational-magnetic playing piece 62A, B and C, it becomes increasingly difficult to construct a fully rotating train of rotational-magnetic playing pieces 62A, B and C, due to the unintended interference (counter-productive interaction) of previously placed rotational-magnetic playing pieces 62A, B and C which acts to lock up portions of the path formed. As space becomes less available along journal hole array 112, a player becomes more limited in availability of successful positions for productive placement of rotational-magnetic playing piece 62A, B and C and it becomes more challenging to successfully extend the number of magnetically coupled playing pieces that rotate upon the manual rotation of rotational-magnetic disk crank 74.
A preferred format of play within the scope of the present invention is the ability to form patterns and form numerous variable paths of magnetically coupled rotating elements. Thus the objective of one or more players is to incrementally add rotary construction pieces to journal hole array that form a magnetically coupled path from rotational-magnetic disk crank 74 whereas rotation of rotational-magnetic ring crank will cause all placed rotary construction pieces to also rotate and experience relative motion. Such patterns can take on numbers shapes and depict things such as robots or other objects. Patterns may have various degrees of symmetry and may have triangular, rectangular or circular paths.
An alternative format of play of the present invention is a construction type path-forming challenge to maximize the number of magnetically coupled rotary construction pieces that can be attached to the “gear train” before a lock up occurs that prevents one or more rotary construction pieces from rotating. According to this format, a multi-player game would instruct players to take turns adding rotary construction pieces. The player that causes magnetic lockup of one or more rotary playing through counter-productive placement of rotary construction pieces looses the game. Thus loss would be incurred either through poor placement strategy or a lack of placement options due to congestion of rotary construction pieces covering most of the journal board. Thus an enjoyable and intellectually demanding method of play is to maximize the number of rotary construction pieces added to the “gear train” before “lock-up” is encountered.
Thus it will be come apparent to one skilled in the art that the present invention provides an interactive apparatus for exploring the principles of magnetic coupling and relative motion. Numerous other formats are also envisioned including the goal to produce specific patterns or to link a rotational-magnetic playing piece on one position on the journal board to one or more rotational-magnetic pieces at a distant spaced apart location. Such an interactive apparatus is so adapted to be both enjoyable and intellectually stimulating.
Referring to
Although not necessary to the embodiment, both configurations rely on centrally located rotational-magnetic disk crank 74 to initiate rotation of all magnetically coupled playing pieces. In addition to having differing patterns
An interchangeable construction apparatus of this size is provided to facilitate play whereas a large number of rotational-magnetic playing pieces can be magnetically coupled for producing relative motion resultant from the hand rotation of a single drive crank. Numerous path formations and patterns can be constructed as journal hole array 122 is of sufficient size and density for adding a substantial number of rotational-magnetic playing piece providing extended play for making the construction device more enjoyable and captivating for the players.
Referring to
Referring to
Circular journal board 30 is characterized with a top surface 35 and bottom surface 36. Annular slot 32 extends below top surface 35 and is of sufficient width to accommodate ring body 90 of rotational-magnetic ring crank 89. Annular slot 32 thus provides a means of concentrically locating ring body 89 around journal hole array 31 and maintaining a substantially fixed axis of rotation for rotational-magnetic ring crank 89. Journal board 30 further comprises feet 34 which extend from bottom surface 36 and provide support to journal board 30. Feet 34 preferably are rubber or a gripping material to counteract torque applied by rotational-magnetic ring crank 89 during play. While feet 34 are shown as three, a larger number of feet are likely preferred to prevent tilting of journal board 30 during manipulation of rotational-magnetic ring crank 89.
Ring crank 89 comprises ring body 90 having top face 92, bottom face (not shown), inside face 93 and outside face 94. Internal magnets 96 are displaced in a circular pattern near inside face 93. Circular pattern of internal magnets 96 are characterized with an alternating radial polarity whereas alternating north and south poles are oriented inward toward journal hole array 31 to facilitate magnetic coupling with rotational-magnetic playing pieces 62A, B and C. Internal magnets 96 are also characterized with a substantially equivalent circular pitch as radial magnets 23 or rotational-magnetic playing pieces 62A, B and C. Thus rotational-magnetic ring crank provides inward magnetic coupling with rotational-magnetic playing pieces 62A, B and C when placed in journal hole array 31 in a pivot position proximal to inside face 93 such that when rotational-magnetic ring crank 89 is rotated, one or more rotational-magnetic playing pieces 62A, B and C will also rotate and experience relative motion. In the embodiment shown ring body 89 comprises 108 rectangular magnets 96 around inside face 93.
According to the third preferred embodiment, rotational-magnetic ring crank 40 also comprises revolving handle 97 extending from top face 92 of ring body 91. Revolving handle 97, being able to freely spin and being mechanically coupled to ring body 91, enables a player to operate the rotational-magnetic ring crank 89 like a crank to provide continuous rotation. Rotational-magnetic ring crank 89 is preferably made of a low friction polymer material or alternatively comprises a low friction film affixed to contacting faces 95 and 93 or 94.
Optionally ring body 90 may further comprises a catch means (not shown) which interfaces with an undercut (not shown) of journal board 30 to prevent rotational-magnetic ring crank 89 from dislodging out of annular slot 32 during manual revolution of rotational-magnetic ring crank 89. Such catch means could be a snap-fit interface or utilize spring plungers which lock into a recess to maintain attachment of rotational-magnetic ring crank 89 to journal board 30. Although a retention means can optionally be added, this is not instrumental for practicing the inventions whereas, in most embodiments, rotational-magnetic ring crank 89 is of sufficient mass not to be easily dislodged from annular slot 32 of journal board 30.
A particular advantage of the third preferred embodiment of
Referring to
In reference to
With regard to
With regard to
With regard to
With regard to
As shown in the visual indication means 87E, 88E, and 89E of
With regard to
With regard to
Numerous other design and configurations of graphical indications means for rotational-magnetic playing pieces are envisioned under the scope of the present inventions. Graphical cover plates provided are removable and interchangeable as to allow a user to explore the visual effects of not only construction piece pattern arrangement but the selection of graphical cover plates to attach thereon. Thus the present invention of a rotational-magnetic construction set allows for a high degree of customization.
Referring to
Referring to
A significant advantage a construction set according to the alternative embodiment of
Additionally, the alternative embodiment of
Like previous embodiments, the circular magnetic pitch P174 of rotational-magnetic disk crank 174 and circular pitch P162C of rotational-magnetic playing piece 162C are substantially equivalent according to the invention as needed for effective coupling between various sized playing pieces. Thus all rotational-magnetic construction pieces including disk crank 174 and large, medium and small rotational-magnetic construction pieces according to the present invention will have a substantially equivalent circular pitch for providing interchangeability whereas all rotational-magnetic construction pieces can be effectively coupled together.
The maximum working depth Dw of
Other embodiments within the scope of the invention include rotational-magnetic playing pieces configured for magnetic coupling whereas embedded magnets of some rotary playing piece are all arranged in an outward north polarity while playing pieces within the construction have magnets all arranged with an outwardly south polarity. Correspondingly, the principal magnetic interaction between proximally placed rotational playing pieces could be either repulsion or attraction depending on the combination. For example, if a playing piece of outwardly north magnetization was placed near a playing piece of outwardly south magnetization the magnetic coupling would be primarily facilitated by the attraction of opposite poles of interacting magnets. On the other hand, if a playing piece of outwardly north magnetization was placed near a playing piece also of outwardly north magnetization, magnetic coupling between this pair would be facilitated by the repulsion of like poles of interacting magnetic.
In addition, it is envisioned within the scope of the invention to include magnetically susceptible ferromagnetic or “soft magnetic” material between or around permanent magnets to help direct magnetic flux and to optimize magnetic coupling between rotational-magnetic playing pieces.
Although magnetic elements are shown as block magnets, alternative embodiments could utilize magnets that are cylindrical, pie-shaped or of other variable geometry.
Although the present invention has been described herein with reference to a particular embodiment, it will be understood that this description is exemplary in nature and is not considered as a limitation on the scope of the invention. The scope and spirit of the present invention is therefore only limited by the appended claims and the reasonable interpretation thereof.
This application claims the benefit of priority of U.S. Provisional Patent Application No. 61/033,722 filed 04 Mar. 2008, of U.S. Provisional Patent Application No. 61/041,831 filed 02 Apr. 2008, of U.S. Provisional Patent Application No. 61/146,793 filed 23 Jan. 2009, and each of which is incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US09/36014 | 3/4/2009 | WO | 00 | 8/25/2010 |
Number | Date | Country | |
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61033722 | Mar 2008 | US | |
61041831 | Apr 2008 | US | |
61146793 | Jan 2009 | US |