US20140349545A1 - Building Elements with Sonic Actuation - Google Patents
Building Elements with Sonic Actuation Download PDFInfo
- Publication number
- US20140349545A1 US20140349545A1 US13/899,490 US201313899490A US2014349545A1 US 20140349545 A1 US20140349545 A1 US 20140349545A1 US 201313899490 A US201313899490 A US 201313899490A US 2014349545 A1 US2014349545 A1 US 2014349545A1
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- United States
- Prior art keywords
- building element
- permanent magnet
- coil
- vibration
- bristles
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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Classifications
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- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63H—TOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
- A63H33/00—Other toys
- A63H33/04—Building blocks, strips, or similar building parts
- A63H33/046—Building blocks, strips, or similar building parts comprising magnetic interaction means, e.g. holding together by magnetic attraction
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- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63H—TOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
- A63H33/00—Other toys
- A63H33/04—Building blocks, strips, or similar building parts
- A63H33/042—Mechanical, electrical, optical, pneumatic or hydraulic arrangements; Motors
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- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63H—TOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
- A63H33/00—Other toys
- A63H33/04—Building blocks, strips, or similar building parts
- A63H33/06—Building blocks, strips, or similar building parts to be assembled without the use of additional elements
- A63H33/062—Building blocks, strips, or similar building parts to be assembled without the use of additional elements with clip or snap mechanisms
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- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63H—TOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
- A63H33/00—Other toys
- A63H33/04—Building blocks, strips, or similar building parts
- A63H33/06—Building blocks, strips, or similar building parts to be assembled without the use of additional elements
- A63H33/08—Building blocks, strips, or similar building parts to be assembled without the use of additional elements provided with complementary holes, grooves, or protuberances, e.g. dovetails
- A63H33/086—Building blocks, strips, or similar building parts to be assembled without the use of additional elements provided with complementary holes, grooves, or protuberances, e.g. dovetails with primary projections fitting by friction in complementary spaces between secondary projections, e.g. sidewalls
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- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63H—TOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
- A63H33/00—Other toys
- A63H33/04—Building blocks, strips, or similar building parts
- A63H33/14—Building blocks, strips, or similar building parts specially adapted to be assembled by adhesive or cement
Definitions
- the disclosed subject matter relates to toy building elements having sonic actuation.
- toys that move.
- movement or animation in toys can be produced using a motor and a set of gears, shafts, and linkages mechanically coupled to the motor and to other parts of the toy.
- Toy construction sets are made up of a plurality of building elements, which include coupling mechanisms such as studs or recesses of specific heights and placement to enable interconnection with other building elements.
- a toy construction system includes a plurality of interconnectible building elements; a control system that generates an electromagnetic signal; a vibration speaker; and a building element apparatus that houses the vibration speaker.
- the vibration speaker includes a permanent magnet that is moveable; a coil positioned near the permanent magnet and moveable relative to the permanent magnet, the coil configured to receive the electromagnetic signal from the control system such that the coil, the permanent magnet, or both vibrate in a manner that is based on the electromagnetic signal; and a sound producer including a diaphragm that is mechanically linked to the coil to vibrate with the coil as the coil vibrates.
- the building element apparatus is mechanically linked to the permanent magnet of the vibration speaker.
- the coil vibrates relative to the permanent magnet when the electromagnetic signal includes frequencies within a first frequency range, the vibration of the coil causing the diaphragm to vibrate and produce an audible sound. And, the permanent magnet vibrates when the electromagnetic signal includes frequencies within a second frequency range, the vibration of the permanent magnet causing the building element apparatus to vibrate.
- the building element apparatus can include a top surface including coupling mechanisms and a bottom surface including coupling mechanisms; and both the top surface and the bottom surface can be caused to vibrate due to the vibration of the permanent magnet.
- the system can include one or more vibration isolator devices each having a coupling mechanism that mates with the coupling mechanisms of the building element apparatus.
- the building element apparatus and the vibration speaker can be mechanically and fixedly linked together.
- the vibration speaker can include a base on which the permanent magnet is moveably mounted, the building element apparatus and the vibration speaker base being fixed together.
- the system can include a bristle module including a bristle pad positioned between a first building element and a second building element, the first building element connectible to the building element apparatus, where the vibration of the building element apparatus causes the first building element to vibrate, the vibration of the first building element is converted into a unidirectional movement of the second building element by way of the bristle pad.
- the bristle pad can include a plurality of slantable bristles extending below a plate, the plate sized to fit within an opening of the second building element and the bristles resting on a top surface of the first building element.
- the control system can be within the building element apparatus.
- the building element apparatus can include a platform building element.
- the building element apparatus can completely enclose the vibration speaker.
- a toy in other general aspect, includes a control system that generates an electromagnetic signal; a building element apparatus having coupling mechanisms on at least two exterior surfaces of a housing, the coupling mechanisms for connecting to building elements of a toy construction system, the building element apparatus housing containing a vibration speaker; and a toy component that is mechanically linked to the permanent magnet.
- the vibration speaker includes a permanent magnet that is moveable relative to a base; a coil positioned near the permanent magnet, the coil moveable relative to the permanent magnet, the coil configured to receive the electromagnetic signal from the control system such that both the coil and the permanent magnet vibrate at the same time in manners that are based on the frequencies of the electromagnetic signal; and a sound producer including a diaphragm that is mechanically linked to the coil to move with the coil as the coil moves.
- the simultaneous vibration of the diaphragm and the permanent magnet causes the simultaneous vibration of the at least two exterior surfaces of the building element apparatus, movement of the toy component, and the production of audible sound that complements the toy component movement.
- Implementations can include one or more of the following features.
- the at least two exterior surfaces of the building element apparatus can include at least two opposite sides of the building element apparatus.
- the at least two opposite sides of the building element can include a top side of the building element and a bottom side of the building element.
- the simultaneous vibration of the diaphragm and the permanent magnet can cause the housing of the building element apparatus to vibrate in a plurality of directions.
- FIG. 1 is a block diagram of a toy construction system that uses a vibration speaker to produce both sound and tactile vibrations;
- FIGS. 2A and 2B are block diagrams of exemplary toy construction systems
- FIG. 3A is a perspective view of an exemplary vibration speaker that can be used in the toy construction systems of FIGS. 1 , 2 A, and 2 B;
- FIG. 3B is a top view of the vibration speaker of FIG. 3A ;
- FIG. 3C is a side cross-sectional view of the vibration speaker of FIG. 3A ;
- FIG. 4A is a perspective view of a self-contained apparatus that includes the vibration speaker and other components of the toy construction system of FIGS. 1 , 2 A, and 2 B;
- FIG. 4B is a side cross-sectional view of the self-contained apparatus of FIG. 4A ;
- FIG. 5A is an exploded perspective view of a self-contained motion converter apparatus that can be used in the toy construction system of FIGS. 1 , 2 A, and 2 B;
- FIG. 5B is a side cross-sectional view of the motion converter apparatus of FIG. 5A ;
- FIG. 6A is an exploded perspective view of an exemplary toy construction system based on the concepts of the system of FIGS. 1 , 2 A, and 2 B;
- FIG. 6B is a side cross-sectional view of the exemplary toy construction system of FIG. 6A ;
- FIG. 6C is a top plan view of an arrangement of building elements and a motion converter apparatus of the exemplary toy construction system of FIGS. 6A and 6B ;
- FIGS. 7A and 7B are side views of an exemplary toy construction system based on the concepts of the system of FIGS. 1 , 2 A, and 2 B;
- FIG. 7C is a top plan view of an arrangement of building elements and a motion converter apparatus of the exemplary toy construction system of FIGS. 7A and 7B ;
- FIG. 8 is a side view of an exemplary toy construction system based on the concepts of the system of FIGS. 1 , 2 A, and 2 B;
- FIGS. 9A-9C are side cross-sectional views of an exemplary reversible bristle device that can be used in the toy construction systems of FIGS. 1 , 2 A, and 2 B;
- FIG. 10A is a perspective view of an exemplary rotary reversible bristle device based on the designs of FIGS. 9A-9C ;
- FIG. 10B is an exploded perspective view of the reversible bristle device of FIG. 10A ;
- FIG. 10C is an exploded side view of the reversible bristle device of FIG. 10A ;
- FIG. 10D is a side cross-sectional view of the reversible bristle device of FIG. 10A ;
- FIG. 11A is a perspective view of an exemplary linear reversible bristle device based on the designs of FIGS. 9A-9C ;
- FIG. 11B is a side cross-sectional view of the reversible bristle device of FIG. 11A ;
- FIG. 11C is a perspective view of a cross-section of the reversible bristle device of FIG. 11A ;
- FIG. 12A is a perspective top view of a male building element that can be used in the toy construction systems of FIGS. 1 , 2 A, 2 B, 4 A, 4 B, 6 A, 6 B, 7 A, 7 B, and 8 ;
- FIG. 12B is a perspective bottom view of the male building element of FIG. 12A ;
- FIG. 12C is a side view of the male building element of FIG. 12A ;
- FIG. 12D is a top view of the male building element of FIG. 12A ;
- FIG. 13A is a perspective top view of a female building element that can be used in the toy construction systems of FIGS. 1 , 2 A, 2 B, 4 A, 4 B, 6 A, 6 B, 7 A, 7 B, and 8 and that can mate with the male building element of FIGS. 12A-12D ;
- FIG. 13B is a perspective bottom view of the female building element of FIG. 13A ;
- FIG. 13C is a side view of the female building element of FIG. 13A ;
- FIG. 13D is a top view of the female building element of FIG. 13A ;
- FIGS. 14A-14F are close-up side views of a bristle in a natural environment that can be used in the toy construction systems of FIGS. 1 , 2 A, 2 B, 4 A, 4 B, 6 A, 6 B, 7 A, 7 B, and 8 ;
- FIG. 15A is a bottom plan view of an exemplary circular bristle arrangement of a motion converter apparatus that can be used in the toy construction systems of FIGS. 1 , 2 A, 2 B, 4 A, 4 B, 6 A, 6 B, 7 A, 7 B, and 8 ;
- FIGS. 15B and 15C are side views of the exemplary bristle arrangement of FIG. 15A ;
- FIG. 16 is a bottom plan view of an exemplary circular bristle arrangement of a motion converter apparatus that can be used in the toy construction systems of FIGS. 1 , 2 A, 2 B, 4 A, 4 B, 6 A, 6 B, 7 A, 7 B, and 8 ;
- FIG. 17 is a bottom plan view of an exemplary rectangular bristle arrangement of a motion converter apparatus that can be used in the toy construction systems of FIGS. 1 , 2 A, 2 B, 4 A, 4 B, 6 A, 6 B, 7 A, 7 B, and 8 , and showing an exemplary motion imparted to the second element;
- FIG. 18A is a side cross-sectional view of a self-contained apparatus that includes the vibration speaker and other components of the toy construction system of FIGS. 1 , 2 A, and 2 B;
- FIG. 18B is a side plan view of the self-contained apparatus of FIG. 18A ;
- FIG. 18C is a perspective view of the self-contained apparatus of FIG. 18A .
- a toy construction system 100 is designed to harness the tactile vibrations 105 produced from a vibration speaker 110 to animate one or more interconnectible building elements 115 of a construction set 117 while also being able to provide sound 120 from the vibration speaker 110 .
- the sound 120 produced by the vibration speaker 110 can be synchronized with the animation of the building elements 115 to provide for more realistic play.
- the vibration speaker 110 can provide a cost-effective solution to provide both motion and sound in a compact design for controlling building elements and other components of construction sets.
- the construction sets therefore can be built with different configurations to provide different animations in combination with sound without requiring an additional vibrating mechanism or motor.
- the vibration speaker 110 can be configured within a building element; and therefore can be repositioned within the construction set depending on the animation desired.
- the vibration speaker 110 produces the tactile vibrations 105 , the sound 120 , or both the tactile vibrations 105 and the sound 120 depending on the frequency characteristics of an electromagnetic signal 125 that is input to a coil 127 within the speaker 110 , the signal 125 being generated from a control system 130 .
- the control system 130 includes internal memory that can store information about components of the system 100 , and a processing unit that accesses the internal memory.
- the control system 130 can also include an input/output device for communicating with other components, such as the arrangement of building elements 115 or other building elements of the construction set 117 , or for communicating with users to enable users to input information to the control system 130 .
- an electrical connection can be connected to the control system 130 and implemented in any of the building elements of the construction set 117 or the arrangement of building elements 115 or to another component such as a base that houses the control system 130 .
- the electrical connection can be a female socket that receives a signal from a male plug to enable users to create their own sound effects and mix animation frequencies that can be input through the male plug, through the female socket, and to the control system 130 .
- the control system 130 can be configured to access information within internal memory housed in these other building elements and can output the signal 125 based on this accessed information.
- the control system 130 receives energy from an energy source 135 (such as a battery) when one or more switches 140 are activated.
- the coil 127 generates a magnetic field that depends on the frequency characteristics of the signal 125 ; and it is the interaction of this generated magnetic field with a nearby permanent magnet 145 within the vibration speaker 110 that is adjusted to thereby produce the tactile vibrations 105 , the sound 120 , or both the tactile vibrations 105 and the sound 120 .
- the tactile vibrations 105 are produced by the motion of the permanent magnet 145 , which is suspended by a suspension system 150 relative to a base 155 of the vibration speaker 110 .
- the permanent magnet 145 gains kinetic energy most effectively (and therefore produces the greatest tactile vibrations) if a driving frequency of the signal 125 is below a predetermined tactile frequency value, the predetermined tactile frequency value depending on the design and types of materials used within the speaker 110 and also on the material and weight of the permanent magnet 145 , which is the heaviest component of the vibration speaker 110 .
- the predetermined tactile frequency value can be about 120 Hz; and the frequency range at which the tactile vibrations 105 are most efficiently produced can be about 70 Hz-120 Hz.
- the permanent magnet 145 is not able to gain kinetic energy as effectively, and there is very little relative motion between the permanent magnet 145 and the coil 127 ; in this situation, most of the kinetic energy is transferred to the coil 127 , which moves and vibrates relative to the permanent magnet 145 due to the interaction of the generated magnetic field with the permanent magnet 145 .
- a diaphragm 160 attached to the coil 127 moves and vibrates with the coil 127 ; and it is the vibration of the diaphragm 160 that causes the oscillation of pressure transmitted through the air adjacent the vibration speaker 110 to produce the sound 120 .
- the predetermined audible frequency value can be about 20 Hz
- the audible frequency range at which the diaphragm 160 efficiently vibrates can be about 20 Hz-20 kHz.
- an electromagnetic signal 125 that has frequency characteristics within both ranges to produce both tactile vibrations 105 and sound 120 from the vibration speaker 110 . It is also possible to adjust the frequency characteristics to select one or the other of the tactile vibrations 105 and the sound 120 to output depending on the design of the building elements 115 and the animation desired.
- the electromagnetic signal 125 can include two sets of signals, one that is within a range of frequencies below the predetermined tactile frequency value and one that is within a range of frequencies above the predetermined audible frequency value; and these signals can be adjusted by the control system 130 , as needed, to produce different sounds and animations in the building elements 115 .
- the tactile vibrations 105 are not harnessed from the sound 120 or from the motion or vibration of the diaphragm 160 (and the coil 127 ), which produces the sound 120 ; rather, the tactile vibrations 105 are harnessed from the motion and vibration of the permanent magnet 145 , and also the base 155 , which moves because the permanent magnet 145 moves. Additionally, the tactile vibrations 105 are mechanically linked to the vibrations of objects (in this case, the magnet 145 or the base 155 ) while the sound 120 is produced from the oscillation of pressure in the compressible medium such as air due to the vibration of the diaphragm 160 .
- the tactile vibrations 105 produced by the vibration speaker 110 are mechanically transmitted to a support building element 165 , which includes one or more coupling mechanisms 167 for enabling the support building element 165 to be interconnected with other building elements of the construction set 117 .
- the support building element 165 can be designed as a platform building element 165 with a flat shape or can be an elongated or rounded building element with any suitable shape that can depend on the toy building built or the application of the vibrations.
- the toy construction system 100 also includes a motion converter apparatus 170 that converts the tactile vibrations 105 into a unidirectional motion 180 , which is thereby transferred to the building elements 115 mechanically linked to the apparatus 170 to cause the building elements 115 to move along a unidirectional path defined by the motion 180 .
- the unidirectional motion 180 can be a rotational motion in which objects travel along a path of a circle or a translatable motion in which objects travel along a linear path.
- the unidirectional motion 180 can be reversed to reverse the path of the building elements 115 by reversing a setting of the motion converter apparatus 170 , as discussed below with respect to FIGS. 2A and 2B .
- the motion converter apparatus 170 can be a self-contained apparatus in which all of the components of the apparatus 170 are within a single building element unit.
- the motion converter apparatus 170 can be made up of distinct components, which are described below.
- the vibration speaker 110 , the support building element 165 , the control system 130 , the one or more switches 140 , and the energy source 135 can be separable components of the toy construction system 100 .
- the vibration speaker 110 , the support building element 165 , the control system 130 , the one or more switches 140 , and the energy source 135 are part of a self-contained apparatus, within a single building element unit.
- an exemplary toy construction system 100 is shown in which the tactile vibrations 105 from the vibration speaker 110 can be mechanically transferred to an optional arrangement 266 of building elements that could include the support building element 165 described above.
- the tactile vibrations 105 can be mechanically transmitted through each of the building elements of the arrangement 266 to the motion converter apparatus 170 , which converts the tactile vibrations 105 into a first unidirectional motion 280 .
- the first unidirectional motion 280 is mechanically transferred to an arrangement 215 of building elements, which, in this example, are shown in a first arrangement to produce a first animation.
- the motion converter apparatus 170 includes a first element 271 that is mechanically constrained by the motion of the tactile vibrations 105 (for example, through the arrangement 266 ) so that the first element 271 vibrates with the tactile vibrations 105 .
- the first element 271 can be a building element that has coupling mechanisms that enable the first element 271 to be interconnected with other building elements of the toy construction set 117 .
- the first element 271 includes a first receiving surface 272 .
- the motion converter apparatus 170 also includes a second element 273 that includes a second receiving surface 274 .
- the first element 271 and the second element 273 are moveable relative to each other.
- the second element 273 can be a building element that has coupling mechanisms that enable the second element 273 to be interconnected with other building elements of the toy construction set 117 .
- the motion converter apparatus 170 includes a set of slantable bristles 275 positioned between the second receiving surface 274 and the first receiving surface 272 ; the bristles 275 being slanted at a first angle relative to a neutral position 201 .
- Each of the bristles 275 makes contact at its first end with the first receiving surface 272 such that the tactile vibrations 105 transmitted to the first element 215 are transmitted to the first ends of the bristles 275 .
- the first ends of the bristles 275 are unconstrained and able to freely move and because of this, the bristles 275 can be considered to be slantable by an angle relative to the neutral position 201 .
- the bristles 275 are set or fixed at a particular angle relative to the neutral position 201 while in a natural environment, which can be considered as the environment in which the bristles 275 are not in contact with, and therefore are not receiving any force from, the first element 271 . Moreover, the second ends of the bristles 275 are constrained by the second receiving surface 274 so that as the second ends of the bristles 275 move, the second receiving surface 274 moves. Additional details about the geometry of the bristles and the arrangement of the bristles 275 are discussed below and with reference to FIGS. 14A-17 .
- the bristles 275 impacts the path of the unidirectional motion 280 ; thus, if the bristles 275 were arranged in a rectangular pattern, then the unidirectional motion 280 would be linear and if the bristles 275 were arranged in a circular pattern, then the unidirectional motion 280 would be circular.
- the bristles 275 are made of a soft, bendable, and non-magnetic material such as urethane or silicon.
- the bristles 275 are made using an injection molding process. Other processes for making the bristles 275 are possible.
- the bristles 275 can be made with casting molds.
- the slanted bristles 275 When the first element 271 vibrates, the slanted bristles 275 are forced to vibrate between bent shapes and the natural shapes of the bristles 275 when in the natural environment, and the amplitude of the vibration periodically bends the bristles 275 at the frequency of the vibration. As the bristles 275 snap back to their natural shapes from being bent, the bristles 275 are forced into the unidirectional motion 280 ; thus, the vibration is converted into the first unidirectional motion 280 , and this motion depends on the angle at which the bristles 275 are slanted.
- the slanted bristles 275 move with the unidirectional motion 280 and cause the second element 273 , which is constrained by the motion of the second ends of the bristles 275 , to also move with the unidirectional motion 280 .
- the unidirectional motion 280 of the second element 273 is mechanically transferred to the arrangement 215 to produce an animation.
- the animation of the arrangement 215 depends on the configuration, geometry, and types of building elements used in the arrangement 215 .
- the unidirectional motion can be reversed to reverse the path of the building elements 215 by reversing or changing a setting of the motion converter apparatus 170 .
- the setting that can be reversed or changed is the angle at which the bristles 275 are slanted relative to a neutral position (which, in FIGS. 2A and 2B is indicated at line 201 ).
- the bristles 275 are slanted at another angle (which is opposite to the angle at which the bristles 275 are slanted in FIG. 2A ) relative to the neutral position 201 . In this way, when the first element 271 vibrates, the slanted bristles 275 in FIG.
- the vibration speaker 310 includes the permanent magnet 345 that floats or is suspended from the base 355 by way of a suspension system 350 (which, in this example, is a spider structure).
- the vibration speaker 310 also includes the diaphragm 360 that is mechanically linked to the coil 327 . Vibrations of the permanent magnet 345 occur at particular frequencies of the signal 125 , and these vibrations are transferred to the suspension system 350 and to the base 355 .
- the permanent magnet 345 can be made of any material that can be permanently magnetized.
- the magnet 345 can be made of a rare earth material such as neodymium or it can be made of a nonmetallic, ceramic-like ferromagnetic compound such as ferric oxide or ferrite.
- the suspension system 350 can be made of a material that is elastic; examples of the material used in the suspension system 350 include plastic and metal. The suspension system 350 can be adjusted to have a particular elasticity that depends on the materials used and on the weight and material of the magnet 345 that it suspends.
- the vibration speaker 110 , the support building element 165 , the control system 130 , the one or more switches 140 , and the energy source 135 can be configured within an exemplary self-contained apparatus 485 .
- the support building element 465 and the vibration speaker 410 are suspended by a suspension 486 or 487 over a base 488 , which houses the control system 430 and the energy source 435 .
- the suspension 487 is a porous structure such as foam and the suspension 486 is a solid/pliable structure such as a spring.
- suspensions can be used to suspend the support building element 465 and the vibration speaker 410 above the base 488 to enable the free movement of these components.
- Other types of suspension structures are possible.
- the suspension 486 or 487 enables the vibrations 105 from the vibration speaker 410 to be freely transmitted to the support building element 465 .
- the base 488 can also include one or more coupling mechanisms 489 such as recesses for interconnecting with other building elements of the construction set 117 .
- an exemplary self-contained motion converter apparatus 570 is designed as a building element that can be connected with other building elements of the construction set 117 .
- the motion converter apparatus 570 includes a first building element 571 , a second building element 573 , and a plurality of bristles 575 between the first building element 571 and the second building element 573 .
- the first and second building elements are moveable relative to each other along a unidirectional path, yet they are also constrained such that they cannot move along paths other than the unidirectional path (for example, along a direction perpendicular to the unidirectional motion that defines the unidirectional path).
- the second building element 573 is rotatable relative to the first building element 571 about the axis 501 but the second building element 573 is not translatable relative to the first building element 571 along the direction of the axis 501 by more than enough distance to enable this free rotation between the elements 571 , 573 .
- the first building element 571 includes coupling mechanisms such as recesses 576 that enable the element 571 to be interconnected with other building elements of the construction set 117 .
- the first building element 571 also includes a first receiving surface 572 that faces the bristles 575 .
- the first building element 571 includes a first connector 577 positioned such that the axis 501 intersects the center of the first connector 577 .
- the first connector 577 enables attachment between the first building element 571 and the second building element 573 , as discussed below.
- the first building element 571 is the element that is in contact with and constrained by the tactile vibrations 105 so that the first building element 571 vibrates with the tactile vibrations 105 .
- the second building element 573 includes coupling mechanisms such as studs 578 that enable the element 573 to be interconnected with other building elements of the construction set 117 .
- the second building element 573 also includes a second receiving surface 574 that faces the first building element 571 , and a second connector 579 that mates with the first connector 577 to enable the relative motion of the elements 573 , 571 along the unidirectional path but to constrain the elements 573 , 571 along directions perpendicular to the unidirectional path.
- the bristles 575 are slanted at a first angle relative to a neutral position or axis, which, in this particular example, extends along the axis 501 .
- Each of the bristles 575 makes contact at its first free end with the first receiving surface 572 such that the tactile vibrations 105 transmitted to the first building element 571 are transmitted to the first ends of the bristles 575 .
- the second ends of the bristles 575 are constrained by the second receiving surface 574 so that as the second ends of the bristles 575 move, the second receiving surface 574 moves.
- the second ends of the bristles 575 are fixed to a top plate 537 , which is fixed to the second receiving surface 574 .
- the second ends of the bristles 575 are fixed directly to the second receiving surface 574 .
- the slanted bristles 575 are forced to vibrate, and the amplitude of the vibration periodically bends the bristles 575 at the frequency of the vibration.
- the bristles 575 snap back from being bent, the bristles 575 are forced into a unidirectional motion that depends on the angle at which the bristles 575 are slanted relative to the neutral axis, which is the axis 501 .
- the unidirectional motion is a circular motion; the slanted bristles 575 rotate about the axis 501 and cause the second building element 573 (which is constrained by the motion of the second ends of the bristles 575 ) to also rotate about the second axis 501 .
- the direction of rotation depends on the angle at which the bristles 575 are slanted relative to the neutral axis which is the axis 501 .
- an exemplary toy construction system includes the self-contained apparatus 485 that houses the control system 430 , the one or more switches 440 , and the energy source 435 and suspends the vibration speaker 410 and the support building element 465 .
- an arrangement 666 includes four 2 ⁇ 2 building elements mechanically connected to the support building element 465 .
- the motion converter apparatus 570 is mechanically connected to the top building element of the arrangement 666 to convert the vibrations 105 produced by the vibration speaker 410 within the apparatus 485 into a circular unidirectional motion 680 that causes an arrangement 615 of building elements to rotate about the central axis 501 of the apparatus 570 .
- the arrangement 615 is designed to resemble a rotor system of a helicopter.
- the building elements of the arrangement 615 include coupling mechanisms such as studs for connection to other elements of the toy construction set 117 .
- the vibrations 105 from the vibration speaker 110 which are transmitted through the support building element 165 , are transmitted to a remote location by way of an elongated building element 771 , which can be considered as the first element 271 of the motion converter apparatus 170 .
- the bristles 775 are positioned next to and contacting the elongated building element 771 to thereby convert the vibrations 105 into a first unidirectional motion 780 of a second element 773 , which is then transmitted to the arrangement of building elements 115 . As shown in FIG.
- the vibrations 105 are converted into a second unidirectional motion 781 of the second element 773 .
- the vibrations 105 that can be produced by the vibration speaker 110 at one location of the construction system 100 can be transmitted across various elements of the system 100 to a remote position at another distinct location of the construction system 100 .
- the elongated building element 771 may have a smooth surface over which the bristles 775 are placed; and the bristles 775 can be in a rectangular arrangement such that the vibrations 105 cause the bristles 775 and also the second element 773 to move along a linear unidirectional path 780 .
- the vibrations from the vibration speaker 110 which are transmitted through the support building element 165 , are transmitted to a remote location by way of an arrangement 866 that includes an elongated building element 868 that is interconnected with the support building element 165 , and a box-like building element 869 that is interconnected or joined with the elongated building element 868 .
- a motion converter apparatus 870 is mechanically linked with the box-like building element 869 and the arrangement of building elements 115 is interconnected with the motion converter apparatus 870 .
- the vibrations 105 produced by the vibration speaker 110 are transmitted through the arrangement 866 , namely, through the elongated building element 868 and the box-like building element 869 , which is remote from the support building element 165 .
- the motion converter apparatus 870 converts the vibrations 105 into the unidirectional motion 880 , which is transmitted to the building elements 115 .
- the bristles of the motion converter apparatus 170 can be incorporated into a reversible bristle device 990 that includes a set of slantable bristles 975 unconstrained at a first end while fixed at a second end to a cap 973 , which serves the same purpose as the second element 273 detailed above.
- the cap 973 is moveable relative to a base 991 along a first path 998 away from or toward a neutral position A (shown in FIG. 9A ) and that is constrained relative to the base 991 along a second path 999 that is perpendicular to the first path.
- the neutral position A is a position in which the bristles 975 are unslanted relative to the first receiving surface 272 (which is shown in FIG. 9A ), which is the vibrating surface that the bristles 975 contact to enable motion conversion. In other words, in the neutral position A, the bristles 975 are normal to the plane of the first receiving surface 272 .
- the base 991 has a plurality of through holes 992 through which the first end of the bristles 975 extend.
- the cap 973 is constrained relative to the base along the second path 999 so that the cap 973 and the base 991 can be held together as a self-contained unit.
- the cap 973 and the base 991 include mating connection mechanisms.
- the cap 973 can include a flange 993 and the base 991 can include clips 994 that extend above the flange 993 so that the cap 973 is unable to move a significant amount along the second path 999 .
- Some motion along the second path 999 may be needed to enable the cap 973 to move freely relative to the base 991 along the first path 998 .
- the cap 973 can be moved relative to the base 991 along a first direction 996 of the first path 998 to a position B and fixed in position B relative to the neutral position A.
- the bristles 975 are slanted in a first manner relative to the neutral direction (which extends along the second path 999 ).
- the bristles 975 of the bristle device 900 act to convert vibrations 105 applied to the first receiving surface 272 into a first unidirectional motion (which would actually be in the first direction 996 ).
- FIG. 9B the cap 973 can be moved relative to the base 991 along a first direction 996 of the first path 998 to a position B and fixed in position B relative to the neutral position A.
- the bristles 975 are slanted in a first manner relative to the neutral direction (which extends along the second path 999 ).
- the bristles 975 of the bristle device 900 act to convert vibrations 105 applied to the first receiving surface 272 into a first unidirectional motion (
- the bristle device 900 can be reversed so that the bristles 975 convert the vibrations 105 applied to the first receiving surface 272 into a second unidirectional motion that is opposite to the first direction 996 .
- the cap 973 is moved relative to the base 991 along a second direction 997 of the first path 998 to a position C and then fixed in position C.
- the bristles 975 are slanted in a second manner relative to the neutral direction. In this way, the motion conversion direction of the bristle device 900 is easily reversed by moving the cap 973 relative to the base 991 .
- the cap 973 may or may not include coupling mechanisms (such as studs) for connecting to building elements of the construction set 117 . While such coupling mechanisms are not shown in FIGS. 9A-9C , they are included in the design of FIGS. 10A-10D .
- the bristles 975 , the cap 973 , and the base 991 can be designed to convert the vibrations 105 into a linear unidirectional motion; in this particular case, the bristles 975 , the cap 973 , and the base 991 would have a rectangular geometry.
- the reversible bristle device 990 can also include a fixation apparatus for fixing the base 991 at a particular position or angle relative to the cap 973 and thus ensure that the bristles 975 are held at a certain angle.
- the fixation apparatus can be a frictional engagement between the base 991 and the cap 973 .
- one of the base 991 and the cap 973 can include detents and the other of the base 991 and the cap 973 can include a pressure activated latch.
- one of the base 991 and the cap 973 can include a keyed-out area and the other of the base 991 and the cap 973 can include an extrusion that allows the base 991 to stay at a given angle relative to the cap 973 .
- the reversible bristle device 1090 is designed to convert the vibrations 105 into a rotational or circular motion.
- the bristles 1075 , the cap 1073 , and the base 1091 have circular geometries.
- the reversible bristle device 1090 also includes a plate 1095 that is mechanically linked to the cap 1073 so that the plate 1095 moves as the cap 1073 moves relative to the base 1091 along the first path 1098 away from or toward the neutral position (which is the position shown in FIGS. 10A-10D ).
- the bristles 1075 are connected to the plate 1095 at their second ends to enable the fixation between the second ends of the bristles 1075 and the cap 1073 .
- the plate 1095 can be mechanically linked to the cap 1073 using one or more of adhesive or bonding agents, connection devices, and a frictional engagement.
- the plate 1095 includes an opening 1077 through which a peg 1079 of the cap 1073 is inserted, and the size of the cross-sectional shape of the peg 1079 is complementary to the size of the plate opening 1077 to enable a frictional engagement between the plate 1095 and the peg 1079 to thereby constrain the movement of the plate 1095 to the movement of the peg 1079 and the cap 1073 to which the peg 1079 is attached.
- the cap 1073 includes coupling mechanisms such as studs 1078 for connecting to building elements of the construction set 117 .
- the bristle device 1090 is shown in the neutral position in FIGS. 10A-10D .
- the cap 1073 is rotated relative to the base 1091 along the first path 1098 away from the neutral position (for example, using counterclockwise motion).
- the circular motion can be reversed by rotating the cap 1073 relative to the base 1091 along the first path 1098 using a clockwise motion. In this way, the bristle device 1090 can be easily manipulated to reverse the unidirectional motion produced by the motion converter apparatus 170 .
- the reversible bristle device 1190 is designed to convert the vibrations 105 into a linear motion.
- the bristles 1175 , the cap 1173 , and the base 1191 have rectangular geometries.
- the reversible bristle device 1190 also includes a plate 1195 that is mechanically linked to the cap 1173 so that the plate 1195 moves as the cap 1173 moves relative to the base 1191 along the first path 1198 away from or toward the neutral position (which is the position shown in FIGS. 11A-11C ).
- the bristles 1175 are connected to the plate 1195 at their second ends to enable the fixation between the second ends of the bristles 1175 and the cap 1173 .
- the plate 1195 can be mechanically linked to the cap 1173 using one or more of adhesive or bonding agents, connection devices, and a frictional engagement. While not show, the cap 1173 can include coupling mechanisms such as studs for connecting to building elements of the construction set 117 .
- the bristle device 1190 is shown in the neutral position in FIGS. 11A-11C .
- the cap 1173 is translated relative to the base 1191 along the first path 1198 away from the neutral position (for example, to the right of the page of the drawing) by moving a knob 1184 , which is mechanically linked to the base 1191 , relative to the cap 1173 .
- the knob 1184 is moved along the first path 1198 (to the right of the page)
- the base 1191 moves because the base 1191 is constrained by the knob 1184 , for example, by a direct connection between the base 1191 and the knob 1184 .
- the linear motion can be reversed by moving the knob 1184 along the first path 1198 in the opposite direction, for example, to the left of the page, relative to the cap 1173 .
- the bristle device 1190 can be easily manipulated to reverse the unidirectional motion produced by the motion converter apparatus 170 .
- vibrations 105 produced by the vibration speaker 110 are transmitted through the support building element 165 , and to the motion converter apparatus 170 .
- the vibrations 105 can be mechanically transmitted through each of the building elements of the arrangement 266 to the motion converter apparatus 170 .
- the mechanical transmission can be performed through the coupling mechanisms of the building elements.
- a special mechanical joint can be incorporated into one or more building elements in the toy construction system 100 to enable the mechanical transmission of the vibrations 105 from any one of the building elements to another building element.
- one particular joint is a male and female dovetail; in which the male dovetail 1218 is formed on the building element 1221 and the female dovetail 1319 , which interfits with the male dovetail 1218 , is formed in the building element 1322 .
- the joint can be formed into the building elements by injection molding.
- a close-up of one of the bristles 275 is shown fixed or constrained to the second element 273 and in the neutral position 201 .
- the bristles 275 can be set at an acute angle relative to the neutral position 201 ; the angle selected determines how the second element 273 will move in response to the vibrations 105 imparted to the first element 271 .
- the bristle 275 is at an angle ⁇ 1 from the neutral position 201 and as shown in FIG. 14C , the bristle 275 is at an angle ⁇ 2 from the neutral position 201 .
- the angle selected can be any value from 0° (at the neutral position 201 ) just below 90° (which is close to being flat against the surface of the second element 273 ). Additionally, as discussed in more detail below with respect to FIGS. 15A-15C , 16 , and 17 , the motion converter apparatus 170 can include bristles 275 having variable angles to achieve different results in the motion produced at the second element 273 .
- the length L B of the bristles 275 can be selected based on the geometry of the motion converter apparatus 170 , and also can be selected based on the desired motion to impart to the second element 273 .
- a shorter length L B for the bristles 275 could impart a slower (low speed) motion or a shorter distance of motion to the second element 273 while, as shown in FIG. 14E , a longer length L B for the bristles 275 could impart a faster (high speed) motion or a longer distance of motion to the second element 273 .
- the bristles 275 of the motion converter apparatus 170 can be designed to have variable lengths, to achieve different results in motion produced at the second element 273 .
- the bristles 275 can have a linear or straight geometry (as shown in FIG. 14A ) when in the neutral position 201 (and when not receiving any force from the first element 271 ), other geometries for the bristles 275 can be used either alone or in combination with linear geometries.
- the bristles 275 can have a non-linear geometry, such as the curved geometry shown in FIG. 14F , when in the neutral position 201 and when not receiving any force from the first element 271 .
- angles, geometries, and the lengths of each of the bristles 275 of the motion converter apparatus 170 can be identical to each other. However, it is possible to use different or variable angles, different or variable lengths, and different or variable geometries for the bristles 275 in a single motion converter apparatus 170 .
- bristle 275 arrangements that have simple geometric shapes such as circles and rectangles, which are easily described using mathematics
- the arrangement of bristles 275 could be non-geometric or complex geometries (which would not be easily described using mathematics).
- the arrangement of bristles 275 could be selected or designed to produce a sequence of unidirectional motions or a random, non-vibratory motion.
- an exemplary circular arrangement of bristles 1575 is shown in its natural environment (thus, the first element 271 is not applying any force to the bristles 1575 ).
- the arrangement includes three sets of bristles, 1575 A, 1575 B, and 1575 C, with each set being on a concentric circle having a distinct radius and all of the bristles of every set being constrained by the motion of the monolithic second element 1573 (or the monolithic plate 1595 if a plate is used).
- the bristles in set 1575 A are naturally slanted at an angle ⁇ A
- the bristles in set 1575 B are naturally slanted at angle ⁇ B
- the bristles in set 1575 C are naturally slanted at angle ⁇ C , these angles given relative to the neutral position 1501 , which is shown going into the page in FIG. 15A .
- the angle ⁇ A is greater than the angle ⁇ A , which is greater than the angle ⁇ C .
- FIG. 16 another exemplary circular arrangement of bristles 1675 is shown in its natural environment (thus, the first element 271 is not applying any force to the bristles 1575 ).
- the arrangement includes three sets of bristles, 1675 A, 1675 B, and 1675 C, with each set being on a concentric circle having a distinct radius and the bristles of each set being constrained by the motion of a respective partition or segment 1673 A, 1673 B, 1673 C of the second element 1673 (or the segments of a plate 1695 if a plate is used).
- Each segment 1673 A, 1673 B, 1673 C of the second element 1673 can move independently about the center of the circular arrangement while being constrained along the axial direction.
- the bristles in each of the sets 1675 A, 1675 B, 1675 C can be naturally slanted at distinct angles, or can have distinct lengths or geometries. In other implementations, the bristles in all of the sets 1675 A, 1675 B, 1675 C can be naturally slanted at the same angles.
- this concept of a segmented bristle arrangement and a corresponding segmented second element can be applied to a rectangular geometry.
- the bristles 1775 are segmented into sets 1775 A and 1775 B, which are respectively constrained by second element segments 1773 A and 1773 B.
- a non-linear (for example, circular) unidirectional motion 1780 to the rectangular bristle/second element geometry.
- the vibration speaker 110 , the support building element 165 , the control system 130 , the one or more switches 140 , and the energy source 135 can be configured within an exemplary self-contained apparatus 1885 (or building element apparatus), in which omni-directional vibrations can be transmitted to permit the vibrations to be transferred from more than one surface of the apparatus 1885 , for example, from two distinct and opposite surfaces, as described next.
- the vibrations are produced in all three dimensions because the apparatus 1885 is rigidly fixed to the base 1855 of the vibration speaker 1810 .
- the support building element 1865 and the vibration speaker 1810 are fixedly secured to the building element base 1888 , which houses the control system 130 and the energy source 135 (not shown in FIG. 18A ).
- the base 1855 of the vibration speaker 1810 can be firmly mounted to the support building element 1865
- the support building element 1865 can be firmly mounted or fixed to the building element base 1888 of the apparatus 1885 .
- the building element base 1888 includes one or more coupling mechanisms 1889 such as recesses for interconnecting with other building elements of the construction set 117 .
- the vibration speaker 1810 and the support building element 1865 are not suspended to freely move relative to the building element base 1888 .
- the vibrations 105 from the vibration speaker 1810 are freely transmitted along all directions outward to the outer surfaces of the apparatus 1885 .
- the vibrations can be transmitted in an upward direction to the support building element 1865 and to any building element attached to the support building element 1865 , as discussed previously.
- the vibrations 105 from the vibration speaker 1810 are also freely transmitted along a downward direction to the building element base 1888 and to any building element to which the building element base 1888 is attached.
- the building element base 1888 is connected to a plate 1883 , and the plate 1883 can be attached to isolator devices 1811 , 1812 .
- the isolator devices 1811 , 1812 can be vibration-dampening devices such as rubber pads that prevent the vibrations imparted to the plate 1883 from being imparted to any item on which the plate 1883 is placed.
- the vibrations imparted to the plate 1883 can be transferred to other building elements (such as element 1871 ) attached to a top side of the plate 1883 that are remote from the apparatus 1885 .
Abstract
A toy includes a building element apparatus having coupling mechanisms on at least two exterior surfaces of a housing containing a vibration speaker that includes a permanent magnet that is moveable relative to a base; a coil positioned near the permanent magnet, moveable relative to the permanent magnet, and configured to receive the electromagnetic signal from a control system such that both the coil and the permanent magnet vibrate at the same time in manners that are based on the electromagnetic signal frequencies; and a sound producer including a diaphragm that is mechanically linked to the coil to move with the coil. The simultaneous vibration of the diaphragm and the permanent magnet causes the simultaneous vibration of the at least two exterior surfaces of the building element apparatus, movement of a toy component mechanically linked to the permanent magnet, and the production of audible sound.
Description
- The disclosed subject matter relates to toy building elements having sonic actuation.
- Children enjoy playing and interacting with toys that move. Typically, movement or animation in toys can be produced using a motor and a set of gears, shafts, and linkages mechanically coupled to the motor and to other parts of the toy.
- Toy construction sets are made up of a plurality of building elements, which include coupling mechanisms such as studs or recesses of specific heights and placement to enable interconnection with other building elements.
- In some general aspects, a toy construction system includes a plurality of interconnectible building elements; a control system that generates an electromagnetic signal; a vibration speaker; and a building element apparatus that houses the vibration speaker. The vibration speaker includes a permanent magnet that is moveable; a coil positioned near the permanent magnet and moveable relative to the permanent magnet, the coil configured to receive the electromagnetic signal from the control system such that the coil, the permanent magnet, or both vibrate in a manner that is based on the electromagnetic signal; and a sound producer including a diaphragm that is mechanically linked to the coil to vibrate with the coil as the coil vibrates. The building element apparatus is mechanically linked to the permanent magnet of the vibration speaker.
- The coil vibrates relative to the permanent magnet when the electromagnetic signal includes frequencies within a first frequency range, the vibration of the coil causing the diaphragm to vibrate and produce an audible sound. And, the permanent magnet vibrates when the electromagnetic signal includes frequencies within a second frequency range, the vibration of the permanent magnet causing the building element apparatus to vibrate.
- Implementations can include one or more of the following features. For example, the building element apparatus can include a top surface including coupling mechanisms and a bottom surface including coupling mechanisms; and both the top surface and the bottom surface can be caused to vibrate due to the vibration of the permanent magnet.
- The system can include one or more vibration isolator devices each having a coupling mechanism that mates with the coupling mechanisms of the building element apparatus.
- The building element apparatus and the vibration speaker can be mechanically and fixedly linked together. The vibration speaker can include a base on which the permanent magnet is moveably mounted, the building element apparatus and the vibration speaker base being fixed together.
- The system can include a bristle module including a bristle pad positioned between a first building element and a second building element, the first building element connectible to the building element apparatus, where the vibration of the building element apparatus causes the first building element to vibrate, the vibration of the first building element is converted into a unidirectional movement of the second building element by way of the bristle pad. The bristle pad can include a plurality of slantable bristles extending below a plate, the plate sized to fit within an opening of the second building element and the bristles resting on a top surface of the first building element. The control system can be within the building element apparatus.
- The building element apparatus can include a platform building element. The building element apparatus can completely enclose the vibration speaker.
- In other general aspect, a toy includes a control system that generates an electromagnetic signal; a building element apparatus having coupling mechanisms on at least two exterior surfaces of a housing, the coupling mechanisms for connecting to building elements of a toy construction system, the building element apparatus housing containing a vibration speaker; and a toy component that is mechanically linked to the permanent magnet. The vibration speaker includes a permanent magnet that is moveable relative to a base; a coil positioned near the permanent magnet, the coil moveable relative to the permanent magnet, the coil configured to receive the electromagnetic signal from the control system such that both the coil and the permanent magnet vibrate at the same time in manners that are based on the frequencies of the electromagnetic signal; and a sound producer including a diaphragm that is mechanically linked to the coil to move with the coil as the coil moves. The simultaneous vibration of the diaphragm and the permanent magnet causes the simultaneous vibration of the at least two exterior surfaces of the building element apparatus, movement of the toy component, and the production of audible sound that complements the toy component movement.
- Implementations can include one or more of the following features. For example, the at least two exterior surfaces of the building element apparatus can include at least two opposite sides of the building element apparatus.
- The at least two opposite sides of the building element can include a top side of the building element and a bottom side of the building element.
- The simultaneous vibration of the diaphragm and the permanent magnet can cause the housing of the building element apparatus to vibrate in a plurality of directions.
- The present disclosure is further described in the detailed description that follows, in reference to the noted drawings by way of non-limiting examples of exemplary implementations, in which like reference numerals represent similar parts throughout the several views of the drawings, and wherein:
-
FIG. 1 is a block diagram of a toy construction system that uses a vibration speaker to produce both sound and tactile vibrations; -
FIGS. 2A and 2B are block diagrams of exemplary toy construction systems; -
FIG. 3A is a perspective view of an exemplary vibration speaker that can be used in the toy construction systems ofFIGS. 1 , 2A, and 2B; -
FIG. 3B is a top view of the vibration speaker ofFIG. 3A ; -
FIG. 3C is a side cross-sectional view of the vibration speaker ofFIG. 3A ; -
FIG. 4A is a perspective view of a self-contained apparatus that includes the vibration speaker and other components of the toy construction system ofFIGS. 1 , 2A, and 2B; -
FIG. 4B is a side cross-sectional view of the self-contained apparatus ofFIG. 4A ; -
FIG. 5A is an exploded perspective view of a self-contained motion converter apparatus that can be used in the toy construction system ofFIGS. 1 , 2A, and 2B; -
FIG. 5B is a side cross-sectional view of the motion converter apparatus ofFIG. 5A ; -
FIG. 6A is an exploded perspective view of an exemplary toy construction system based on the concepts of the system ofFIGS. 1 , 2A, and 2B; -
FIG. 6B is a side cross-sectional view of the exemplary toy construction system ofFIG. 6A ; -
FIG. 6C is a top plan view of an arrangement of building elements and a motion converter apparatus of the exemplary toy construction system ofFIGS. 6A and 6B ; -
FIGS. 7A and 7B are side views of an exemplary toy construction system based on the concepts of the system ofFIGS. 1 , 2A, and 2B; -
FIG. 7C is a top plan view of an arrangement of building elements and a motion converter apparatus of the exemplary toy construction system ofFIGS. 7A and 7B ; -
FIG. 8 is a side view of an exemplary toy construction system based on the concepts of the system ofFIGS. 1 , 2A, and 2B; -
FIGS. 9A-9C are side cross-sectional views of an exemplary reversible bristle device that can be used in the toy construction systems ofFIGS. 1 , 2A, and 2B; -
FIG. 10A is a perspective view of an exemplary rotary reversible bristle device based on the designs ofFIGS. 9A-9C ; -
FIG. 10B is an exploded perspective view of the reversible bristle device ofFIG. 10A ; -
FIG. 10C is an exploded side view of the reversible bristle device ofFIG. 10A ; -
FIG. 10D is a side cross-sectional view of the reversible bristle device ofFIG. 10A ; -
FIG. 11A is a perspective view of an exemplary linear reversible bristle device based on the designs ofFIGS. 9A-9C ; -
FIG. 11B is a side cross-sectional view of the reversible bristle device ofFIG. 11A ; -
FIG. 11C is a perspective view of a cross-section of the reversible bristle device ofFIG. 11A ; -
FIG. 12A is a perspective top view of a male building element that can be used in the toy construction systems ofFIGS. 1 , 2A, 2B, 4A, 4B, 6A, 6B, 7A, 7B, and 8; -
FIG. 12B is a perspective bottom view of the male building element ofFIG. 12A ; -
FIG. 12C is a side view of the male building element ofFIG. 12A ; -
FIG. 12D is a top view of the male building element ofFIG. 12A ; -
FIG. 13A is a perspective top view of a female building element that can be used in the toy construction systems ofFIGS. 1 , 2A, 2B, 4A, 4B, 6A, 6B, 7A, 7B, and 8 and that can mate with the male building element ofFIGS. 12A-12D ; -
FIG. 13B is a perspective bottom view of the female building element ofFIG. 13A ; -
FIG. 13C is a side view of the female building element ofFIG. 13A ; -
FIG. 13D is a top view of the female building element ofFIG. 13A ; -
FIGS. 14A-14F are close-up side views of a bristle in a natural environment that can be used in the toy construction systems ofFIGS. 1 , 2A, 2B, 4A, 4B, 6A, 6B, 7A, 7B, and 8; -
FIG. 15A is a bottom plan view of an exemplary circular bristle arrangement of a motion converter apparatus that can be used in the toy construction systems ofFIGS. 1 , 2A, 2B, 4A, 4B, 6A, 6B, 7A, 7B, and 8; -
FIGS. 15B and 15C are side views of the exemplary bristle arrangement ofFIG. 15A ; -
FIG. 16 is a bottom plan view of an exemplary circular bristle arrangement of a motion converter apparatus that can be used in the toy construction systems ofFIGS. 1 , 2A, 2B, 4A, 4B, 6A, 6B, 7A, 7B, and 8; -
FIG. 17 is a bottom plan view of an exemplary rectangular bristle arrangement of a motion converter apparatus that can be used in the toy construction systems ofFIGS. 1 , 2A, 2B, 4A, 4B, 6A, 6B, 7A, 7B, and 8, and showing an exemplary motion imparted to the second element; -
FIG. 18A is a side cross-sectional view of a self-contained apparatus that includes the vibration speaker and other components of the toy construction system ofFIGS. 1 , 2A, and 2B; -
FIG. 18B is a side plan view of the self-contained apparatus ofFIG. 18A ; and -
FIG. 18C is a perspective view of the self-contained apparatus ofFIG. 18A . - The following description provides exemplary implementations only, and is not intended to limit the scope, applicability, or configuration of the disclosure. Rather, the following description of the exemplary implementations provides those skilled in the art with an enabling description for implementing one or more exemplary implementations. Various changes can be made in the function and arrangement of the elements without departing from the spirit and scope of the invention as set forth in the appended claims.
- Referring to
FIG. 1 , atoy construction system 100 is designed to harness thetactile vibrations 105 produced from avibration speaker 110 to animate one or moreinterconnectible building elements 115 of aconstruction set 117 while also being able to provide sound 120 from thevibration speaker 110. Thesound 120 produced by thevibration speaker 110 can be synchronized with the animation of thebuilding elements 115 to provide for more realistic play. Thevibration speaker 110 can provide a cost-effective solution to provide both motion and sound in a compact design for controlling building elements and other components of construction sets. The construction sets therefore can be built with different configurations to provide different animations in combination with sound without requiring an additional vibrating mechanism or motor. Moreover, thevibration speaker 110 can be configured within a building element; and therefore can be repositioned within the construction set depending on the animation desired. - In particular, the
vibration speaker 110 produces thetactile vibrations 105, thesound 120, or both thetactile vibrations 105 and thesound 120 depending on the frequency characteristics of anelectromagnetic signal 125 that is input to acoil 127 within thespeaker 110, thesignal 125 being generated from acontrol system 130. - The
control system 130 includes internal memory that can store information about components of thesystem 100, and a processing unit that accesses the internal memory. Thecontrol system 130 can also include an input/output device for communicating with other components, such as the arrangement of buildingelements 115 or other building elements of the construction set 117, or for communicating with users to enable users to input information to thecontrol system 130. For example, an electrical connection can be connected to thecontrol system 130 and implemented in any of the building elements of the construction set 117 or the arrangement of buildingelements 115 or to another component such as a base that houses thecontrol system 130. The electrical connection can be a female socket that receives a signal from a male plug to enable users to create their own sound effects and mix animation frequencies that can be input through the male plug, through the female socket, and to thecontrol system 130. Thecontrol system 130 can be configured to access information within internal memory housed in these other building elements and can output thesignal 125 based on this accessed information. - The
control system 130 receives energy from an energy source 135 (such as a battery) when one ormore switches 140 are activated. Thecoil 127 generates a magnetic field that depends on the frequency characteristics of thesignal 125; and it is the interaction of this generated magnetic field with a nearbypermanent magnet 145 within thevibration speaker 110 that is adjusted to thereby produce thetactile vibrations 105, thesound 120, or both thetactile vibrations 105 and thesound 120. - The
tactile vibrations 105 are produced by the motion of thepermanent magnet 145, which is suspended by asuspension system 150 relative to abase 155 of thevibration speaker 110. Thepermanent magnet 145 gains kinetic energy most effectively (and therefore produces the greatest tactile vibrations) if a driving frequency of thesignal 125 is below a predetermined tactile frequency value, the predetermined tactile frequency value depending on the design and types of materials used within thespeaker 110 and also on the material and weight of thepermanent magnet 145, which is the heaviest component of thevibration speaker 110. Thus, for apermanent magnet 145 made of ferrite and having asuspension system 150 made of metal, the predetermined tactile frequency value can be about 120 Hz; and the frequency range at which thetactile vibrations 105 are most efficiently produced can be about 70 Hz-120 Hz. - On the other hand, for driving frequencies within the
signal 125 that are greater than an predetermined audible frequency value, thepermanent magnet 145 is not able to gain kinetic energy as effectively, and there is very little relative motion between thepermanent magnet 145 and thecoil 127; in this situation, most of the kinetic energy is transferred to thecoil 127, which moves and vibrates relative to thepermanent magnet 145 due to the interaction of the generated magnetic field with thepermanent magnet 145. Adiaphragm 160 attached to thecoil 127 moves and vibrates with thecoil 127; and it is the vibration of thediaphragm 160 that causes the oscillation of pressure transmitted through the air adjacent thevibration speaker 110 to produce thesound 120. In one particular example in which thediaphragm 160 is made of Mylar™, the predetermined audible frequency value can be about 20 Hz, and the audible frequency range at which thediaphragm 160 efficiently vibrates can be about 20 Hz-20 kHz. - Thus, it is possible to provide an
electromagnetic signal 125 that has frequency characteristics within both ranges to produce bothtactile vibrations 105 and sound 120 from thevibration speaker 110. It is also possible to adjust the frequency characteristics to select one or the other of thetactile vibrations 105 and thesound 120 to output depending on the design of thebuilding elements 115 and the animation desired. Theelectromagnetic signal 125 can include two sets of signals, one that is within a range of frequencies below the predetermined tactile frequency value and one that is within a range of frequencies above the predetermined audible frequency value; and these signals can be adjusted by thecontrol system 130, as needed, to produce different sounds and animations in thebuilding elements 115. - Importantly, the
tactile vibrations 105 are not harnessed from thesound 120 or from the motion or vibration of the diaphragm 160 (and the coil 127), which produces thesound 120; rather, thetactile vibrations 105 are harnessed from the motion and vibration of thepermanent magnet 145, and also thebase 155, which moves because thepermanent magnet 145 moves. Additionally, thetactile vibrations 105 are mechanically linked to the vibrations of objects (in this case, themagnet 145 or the base 155) while thesound 120 is produced from the oscillation of pressure in the compressible medium such as air due to the vibration of thediaphragm 160. - The
tactile vibrations 105 produced by thevibration speaker 110 are mechanically transmitted to asupport building element 165, which includes one ormore coupling mechanisms 167 for enabling thesupport building element 165 to be interconnected with other building elements of the construction set 117. Thesupport building element 165 can be designed as aplatform building element 165 with a flat shape or can be an elongated or rounded building element with any suitable shape that can depend on the toy building built or the application of the vibrations. Thetoy construction system 100 also includes amotion converter apparatus 170 that converts thetactile vibrations 105 into aunidirectional motion 180, which is thereby transferred to thebuilding elements 115 mechanically linked to theapparatus 170 to cause thebuilding elements 115 to move along a unidirectional path defined by themotion 180. Theunidirectional motion 180 can be a rotational motion in which objects travel along a path of a circle or a translatable motion in which objects travel along a linear path. Theunidirectional motion 180 can be reversed to reverse the path of thebuilding elements 115 by reversing a setting of themotion converter apparatus 170, as discussed below with respect toFIGS. 2A and 2B . - As also discussed below, and as shown in
FIGS. 5A and 5B , themotion converter apparatus 170 can be a self-contained apparatus in which all of the components of theapparatus 170 are within a single building element unit. Alternatively, themotion converter apparatus 170 can be made up of distinct components, which are described below. - The
vibration speaker 110, thesupport building element 165, thecontrol system 130, the one ormore switches 140, and theenergy source 135 can be separable components of thetoy construction system 100. In some implementations, which are described below, thevibration speaker 110, thesupport building element 165, thecontrol system 130, the one ormore switches 140, and theenergy source 135 are part of a self-contained apparatus, within a single building element unit. - Referring also to
FIG. 2A , an exemplarytoy construction system 100 is shown in which thetactile vibrations 105 from thevibration speaker 110 can be mechanically transferred to anoptional arrangement 266 of building elements that could include thesupport building element 165 described above. Thetactile vibrations 105 can be mechanically transmitted through each of the building elements of thearrangement 266 to themotion converter apparatus 170, which converts thetactile vibrations 105 into a firstunidirectional motion 280. The firstunidirectional motion 280 is mechanically transferred to anarrangement 215 of building elements, which, in this example, are shown in a first arrangement to produce a first animation. - The
motion converter apparatus 170 includes afirst element 271 that is mechanically constrained by the motion of the tactile vibrations 105 (for example, through the arrangement 266) so that thefirst element 271 vibrates with thetactile vibrations 105. In some examples provided below, thefirst element 271 can be a building element that has coupling mechanisms that enable thefirst element 271 to be interconnected with other building elements of the toy construction set 117. Thefirst element 271 includes afirst receiving surface 272. Themotion converter apparatus 170 also includes asecond element 273 that includes asecond receiving surface 274. Thefirst element 271 and thesecond element 273 are moveable relative to each other. Thesecond element 273 can be a building element that has coupling mechanisms that enable thesecond element 273 to be interconnected with other building elements of the toy construction set 117. - The
motion converter apparatus 170 includes a set of slantable bristles 275 positioned between thesecond receiving surface 274 and thefirst receiving surface 272; thebristles 275 being slanted at a first angle relative to aneutral position 201. Each of thebristles 275 makes contact at its first end with thefirst receiving surface 272 such that thetactile vibrations 105 transmitted to thefirst element 215 are transmitted to the first ends of thebristles 275. The first ends of thebristles 275 are unconstrained and able to freely move and because of this, thebristles 275 can be considered to be slantable by an angle relative to theneutral position 201. Thebristles 275 are set or fixed at a particular angle relative to theneutral position 201 while in a natural environment, which can be considered as the environment in which thebristles 275 are not in contact with, and therefore are not receiving any force from, thefirst element 271. Moreover, the second ends of thebristles 275 are constrained by thesecond receiving surface 274 so that as the second ends of thebristles 275 move, thesecond receiving surface 274 moves. Additional details about the geometry of the bristles and the arrangement of thebristles 275 are discussed below and with reference toFIGS. 14A-17 . - The arrangement of the
bristles 275 impacts the path of theunidirectional motion 280; thus, if thebristles 275 were arranged in a rectangular pattern, then theunidirectional motion 280 would be linear and if thebristles 275 were arranged in a circular pattern, then theunidirectional motion 280 would be circular. To enable the bending of thebristles 275, thebristles 275 are made of a soft, bendable, and non-magnetic material such as urethane or silicon. In some implementations, thebristles 275 are made using an injection molding process. Other processes for making thebristles 275 are possible. For example, thebristles 275 can be made with casting molds. - When the
first element 271 vibrates, the slanted bristles 275 are forced to vibrate between bent shapes and the natural shapes of thebristles 275 when in the natural environment, and the amplitude of the vibration periodically bends thebristles 275 at the frequency of the vibration. As thebristles 275 snap back to their natural shapes from being bent, thebristles 275 are forced into theunidirectional motion 280; thus, the vibration is converted into the firstunidirectional motion 280, and this motion depends on the angle at which thebristles 275 are slanted. The slanted bristles 275 move with theunidirectional motion 280 and cause thesecond element 273, which is constrained by the motion of the second ends of thebristles 275, to also move with theunidirectional motion 280. Theunidirectional motion 280 of thesecond element 273 is mechanically transferred to thearrangement 215 to produce an animation. The animation of thearrangement 215 depends on the configuration, geometry, and types of building elements used in thearrangement 215. - Referring also to
FIG. 2B , as mentioned above, the unidirectional motion can be reversed to reverse the path of thebuilding elements 215 by reversing or changing a setting of themotion converter apparatus 170. In this example, the setting that can be reversed or changed is the angle at which thebristles 275 are slanted relative to a neutral position (which, inFIGS. 2A and 2B is indicated at line 201). Thus, inFIG. 2B , thebristles 275 are slanted at another angle (which is opposite to the angle at which thebristles 275 are slanted inFIG. 2A ) relative to theneutral position 201. In this way, when thefirst element 271 vibrates, the slanted bristles 275 inFIG. 2B are forced to vibrate, and this vibration is converted into a secondunidirectional motion 281 that depends on the angle at which thebristles 275 are slanted inFIG. 2B . The slanted bristles 275 that move with the secondunidirectional motion 281 cause the second element 273 (which is constrained by the motion of the second ends of the bristles 275) to also move with the secondunidirectional motion 281 along the second unidirectional path (which is opposite to the first unidirectional path). Thus, thearrangement 215 produces a second animation. - Referring to
FIGS. 3A-C , anexemplary vibration speaker 310 is shown. Thevibration speaker 310 includes thepermanent magnet 345 that floats or is suspended from the base 355 by way of a suspension system 350 (which, in this example, is a spider structure). Thevibration speaker 310 also includes thediaphragm 360 that is mechanically linked to thecoil 327. Vibrations of thepermanent magnet 345 occur at particular frequencies of thesignal 125, and these vibrations are transferred to thesuspension system 350 and to thebase 355. - The
permanent magnet 345 can be made of any material that can be permanently magnetized. Thus, for example, themagnet 345 can be made of a rare earth material such as neodymium or it can be made of a nonmetallic, ceramic-like ferromagnetic compound such as ferric oxide or ferrite. Thesuspension system 350 can be made of a material that is elastic; examples of the material used in thesuspension system 350 include plastic and metal. Thesuspension system 350 can be adjusted to have a particular elasticity that depends on the materials used and on the weight and material of themagnet 345 that it suspends. - Referring to
FIGS. 4A and 4B , and as mentioned above, in some implementations, thevibration speaker 110, thesupport building element 165, thecontrol system 130, the one ormore switches 140, and theenergy source 135 can be configured within an exemplary self-containedapparatus 485. In this example, thesupport building element 465 and thevibration speaker 410 are suspended by asuspension base 488, which houses thecontrol system 430 and theenergy source 435. Thesuspension 487 is a porous structure such as foam and thesuspension 486 is a solid/pliable structure such as a spring. Either or both of these types of suspensions can be used to suspend thesupport building element 465 and thevibration speaker 410 above the base 488 to enable the free movement of these components. Other types of suspension structures are possible. In any case, thesuspension vibrations 105 from thevibration speaker 410 to be freely transmitted to thesupport building element 465. The base 488 can also include one ormore coupling mechanisms 489 such as recesses for interconnecting with other building elements of the construction set 117. - Referring to
FIGS. 5A and 5B , an exemplary self-containedmotion converter apparatus 570 is designed as a building element that can be connected with other building elements of the construction set 117. In this example, themotion converter apparatus 570 includes afirst building element 571, asecond building element 573, and a plurality ofbristles 575 between thefirst building element 571 and thesecond building element 573. The first and second building elements are moveable relative to each other along a unidirectional path, yet they are also constrained such that they cannot move along paths other than the unidirectional path (for example, along a direction perpendicular to the unidirectional motion that defines the unidirectional path). In this particular example, thesecond building element 573 is rotatable relative to thefirst building element 571 about theaxis 501 but thesecond building element 573 is not translatable relative to thefirst building element 571 along the direction of theaxis 501 by more than enough distance to enable this free rotation between theelements - The
first building element 571 includes coupling mechanisms such asrecesses 576 that enable theelement 571 to be interconnected with other building elements of the construction set 117. Thefirst building element 571 also includes afirst receiving surface 572 that faces thebristles 575. Thefirst building element 571 includes afirst connector 577 positioned such that theaxis 501 intersects the center of thefirst connector 577. Thefirst connector 577 enables attachment between thefirst building element 571 and thesecond building element 573, as discussed below. Thefirst building element 571 is the element that is in contact with and constrained by thetactile vibrations 105 so that thefirst building element 571 vibrates with thetactile vibrations 105. - The
second building element 573 includes coupling mechanisms such asstuds 578 that enable theelement 573 to be interconnected with other building elements of the construction set 117. Thesecond building element 573 also includes asecond receiving surface 574 that faces thefirst building element 571, and asecond connector 579 that mates with thefirst connector 577 to enable the relative motion of theelements elements - The
bristles 575 are slanted at a first angle relative to a neutral position or axis, which, in this particular example, extends along theaxis 501. Each of thebristles 575 makes contact at its first free end with thefirst receiving surface 572 such that thetactile vibrations 105 transmitted to thefirst building element 571 are transmitted to the first ends of thebristles 575. Moreover, the second ends of thebristles 575 are constrained by thesecond receiving surface 574 so that as the second ends of thebristles 575 move, thesecond receiving surface 574 moves. In this particular example, the second ends of thebristles 575 are fixed to atop plate 537, which is fixed to thesecond receiving surface 574. In other implementations, the second ends of thebristles 575 are fixed directly to thesecond receiving surface 574. - Thus, when the
first building element 571 vibrates, the slanted bristles 575 are forced to vibrate, and the amplitude of the vibration periodically bends thebristles 575 at the frequency of the vibration. As thebristles 575 snap back from being bent, thebristles 575 are forced into a unidirectional motion that depends on the angle at which thebristles 575 are slanted relative to the neutral axis, which is theaxis 501. In this example, the unidirectional motion is a circular motion; the slanted bristles 575 rotate about theaxis 501 and cause the second building element 573 (which is constrained by the motion of the second ends of the bristles 575) to also rotate about thesecond axis 501. The direction of rotation depends on the angle at which thebristles 575 are slanted relative to the neutral axis which is theaxis 501. - Referring also to
FIGS. 6A-6C , an exemplary toy construction system is shown that includes the self-containedapparatus 485 that houses thecontrol system 430, the one ormore switches 440, and theenergy source 435 and suspends thevibration speaker 410 and thesupport building element 465. In this example, anarrangement 666 includes four 2×2 building elements mechanically connected to thesupport building element 465. Themotion converter apparatus 570 is mechanically connected to the top building element of thearrangement 666 to convert thevibrations 105 produced by thevibration speaker 410 within theapparatus 485 into a circularunidirectional motion 680 that causes anarrangement 615 of building elements to rotate about thecentral axis 501 of theapparatus 570. In this example, thearrangement 615 is designed to resemble a rotor system of a helicopter. The building elements of thearrangement 615 include coupling mechanisms such as studs for connection to other elements of the toy construction set 117. - Referring to
FIG. 7A , in one implementation, thevibrations 105 from thevibration speaker 110, which are transmitted through thesupport building element 165, are transmitted to a remote location by way of anelongated building element 771, which can be considered as thefirst element 271 of themotion converter apparatus 170. In this case, thebristles 775 are positioned next to and contacting theelongated building element 771 to thereby convert thevibrations 105 into a firstunidirectional motion 780 of asecond element 773, which is then transmitted to the arrangement of buildingelements 115. As shown inFIG. 7B , if the angle of thebristles 775 is reversed, then thevibrations 105 are converted into a secondunidirectional motion 781 of thesecond element 773. In this way, thevibrations 105 that can be produced by thevibration speaker 110 at one location of theconstruction system 100 can be transmitted across various elements of thesystem 100 to a remote position at another distinct location of theconstruction system 100. - In this particular example, as more clearly shown in
FIG. 7C , theelongated building element 771 may have a smooth surface over which thebristles 775 are placed; and thebristles 775 can be in a rectangular arrangement such that thevibrations 105 cause thebristles 775 and also thesecond element 773 to move along a linearunidirectional path 780. - Referring to
FIG. 8 , in another implementation, the vibrations from thevibration speaker 110, which are transmitted through thesupport building element 165, are transmitted to a remote location by way of anarrangement 866 that includes anelongated building element 868 that is interconnected with thesupport building element 165, and a box-like building element 869 that is interconnected or joined with theelongated building element 868. Moreover, amotion converter apparatus 870 is mechanically linked with the box-like building element 869 and the arrangement of buildingelements 115 is interconnected with themotion converter apparatus 870. In this particular implementation, thevibrations 105 produced by thevibration speaker 110 are transmitted through thearrangement 866, namely, through theelongated building element 868 and the box-like building element 869, which is remote from thesupport building element 165. Themotion converter apparatus 870 converts thevibrations 105 into theunidirectional motion 880, which is transmitted to thebuilding elements 115. - Referring to
FIGS. 9A-9C , the bristles of themotion converter apparatus 170 can be incorporated into areversible bristle device 990 that includes a set of slantable bristles 975 unconstrained at a first end while fixed at a second end to acap 973, which serves the same purpose as thesecond element 273 detailed above. Thecap 973 is moveable relative to abase 991 along afirst path 998 away from or toward a neutral position A (shown inFIG. 9A ) and that is constrained relative to thebase 991 along asecond path 999 that is perpendicular to the first path. The neutral position A is a position in which thebristles 975 are unslanted relative to the first receiving surface 272 (which is shown inFIG. 9A ), which is the vibrating surface that thebristles 975 contact to enable motion conversion. In other words, in the neutral position A, thebristles 975 are normal to the plane of thefirst receiving surface 272. - The
base 991 has a plurality of throughholes 992 through which the first end of thebristles 975 extend. As mentioned above, thecap 973 is constrained relative to the base along thesecond path 999 so that thecap 973 and the base 991 can be held together as a self-contained unit. To enable this, thecap 973 and the base 991 include mating connection mechanisms. For example, thecap 973 can include aflange 993 and the base 991 can includeclips 994 that extend above theflange 993 so that thecap 973 is unable to move a significant amount along thesecond path 999. Some motion along thesecond path 999 may be needed to enable thecap 973 to move freely relative to thebase 991 along thefirst path 998. - As shown in
FIG. 9B , thecap 973 can be moved relative to thebase 991 along afirst direction 996 of thefirst path 998 to a position B and fixed in position B relative to the neutral position A. In position B, thebristles 975 are slanted in a first manner relative to the neutral direction (which extends along the second path 999). Thus, while in position B, thebristles 975 of the bristle device 900 act to convertvibrations 105 applied to thefirst receiving surface 272 into a first unidirectional motion (which would actually be in the first direction 996). As shown inFIG. 9C , the bristle device 900 can be reversed so that thebristles 975 convert thevibrations 105 applied to thefirst receiving surface 272 into a second unidirectional motion that is opposite to thefirst direction 996. InFIG. 9C , thecap 973 is moved relative to thebase 991 along asecond direction 997 of thefirst path 998 to a position C and then fixed in position C. In position C, thebristles 975 are slanted in a second manner relative to the neutral direction. In this way, the motion conversion direction of the bristle device 900 is easily reversed by moving thecap 973 relative to thebase 991. - The
cap 973 may or may not include coupling mechanisms (such as studs) for connecting to building elements of the construction set 117. While such coupling mechanisms are not shown inFIGS. 9A-9C , they are included in the design ofFIGS. 10A-10D . - The
bristles 975, thecap 973, and the base 991 can be designed to convert thevibrations 105 into a linear unidirectional motion; in this particular case, thebristles 975, thecap 973, and the base 991 would have a rectangular geometry. - The reversible bristle
device 990 can also include a fixation apparatus for fixing the base 991 at a particular position or angle relative to thecap 973 and thus ensure that thebristles 975 are held at a certain angle. The fixation apparatus can be a frictional engagement between the base 991 and thecap 973. For example, one of thebase 991 and thecap 973 can include detents and the other of thebase 991 and thecap 973 can include a pressure activated latch. As another example, one of thebase 991 and thecap 973 can include a keyed-out area and the other of thebase 991 and thecap 973 can include an extrusion that allows the base 991 to stay at a given angle relative to thecap 973. - In other implementations, and with reference to
FIGS. 10A-10D , thereversible bristle device 1090 is designed to convert thevibrations 105 into a rotational or circular motion. In thebristle device 1090, thebristles 1075, thecap 1073, and thebase 1091 have circular geometries. The reversible bristledevice 1090 also includes aplate 1095 that is mechanically linked to thecap 1073 so that theplate 1095 moves as thecap 1073 moves relative to thebase 1091 along thefirst path 1098 away from or toward the neutral position (which is the position shown inFIGS. 10A-10D ). Thebristles 1075 are connected to theplate 1095 at their second ends to enable the fixation between the second ends of thebristles 1075 and thecap 1073. - The
plate 1095 can be mechanically linked to thecap 1073 using one or more of adhesive or bonding agents, connection devices, and a frictional engagement. For example, as shown inFIGS. 10B-10D , theplate 1095 includes anopening 1077 through which apeg 1079 of thecap 1073 is inserted, and the size of the cross-sectional shape of thepeg 1079 is complementary to the size of theplate opening 1077 to enable a frictional engagement between theplate 1095 and thepeg 1079 to thereby constrain the movement of theplate 1095 to the movement of thepeg 1079 and thecap 1073 to which thepeg 1079 is attached. In thebristle device 1090, thecap 1073 includes coupling mechanisms such asstuds 1078 for connecting to building elements of the construction set 117. - The
bristle device 1090 is shown in the neutral position inFIGS. 10A-10D . To active thebristle device 1090 to convertvibrations 105 applied to thefirst receiving surface 272 into a circular or rotational motion, thecap 1073 is rotated relative to thebase 1091 along thefirst path 1098 away from the neutral position (for example, using counterclockwise motion). The circular motion can be reversed by rotating thecap 1073 relative to thebase 1091 along thefirst path 1098 using a clockwise motion. In this way, thebristle device 1090 can be easily manipulated to reverse the unidirectional motion produced by themotion converter apparatus 170. - In other implementations, and with reference to
FIGS. 11A-11C , thereversible bristle device 1190 is designed to convert thevibrations 105 into a linear motion. In thebristle device 1190, thebristles 1175, thecap 1173, and thebase 1191 have rectangular geometries. The reversible bristledevice 1190 also includes aplate 1195 that is mechanically linked to thecap 1173 so that theplate 1195 moves as thecap 1173 moves relative to thebase 1191 along thefirst path 1198 away from or toward the neutral position (which is the position shown inFIGS. 11A-11C ). Thebristles 1175 are connected to theplate 1195 at their second ends to enable the fixation between the second ends of thebristles 1175 and thecap 1173. - The
plate 1195 can be mechanically linked to thecap 1173 using one or more of adhesive or bonding agents, connection devices, and a frictional engagement. While not show, thecap 1173 can include coupling mechanisms such as studs for connecting to building elements of the construction set 117. - The
bristle device 1190 is shown in the neutral position inFIGS. 11A-11C . To active thebristle device 1190 to convertvibrations 105 applied to thefirst receiving surface 272 into a linear motion, thecap 1173 is translated relative to thebase 1191 along thefirst path 1198 away from the neutral position (for example, to the right of the page of the drawing) by moving aknob 1184, which is mechanically linked to thebase 1191, relative to thecap 1173. As theknob 1184 is moved along the first path 1198 (to the right of the page), thebase 1191 moves because thebase 1191 is constrained by theknob 1184, for example, by a direct connection between the base 1191 and theknob 1184. The linear motion can be reversed by moving theknob 1184 along thefirst path 1198 in the opposite direction, for example, to the left of the page, relative to thecap 1173. In this way, thebristle device 1190 can be easily manipulated to reverse the unidirectional motion produced by themotion converter apparatus 170. - As discussed above,
vibrations 105 produced by thevibration speaker 110 are transmitted through thesupport building element 165, and to themotion converter apparatus 170. Thevibrations 105 can be mechanically transmitted through each of the building elements of thearrangement 266 to themotion converter apparatus 170. The mechanical transmission can be performed through the coupling mechanisms of the building elements. Thus, it is the connection between the coupling mechanisms of adjacent building elements that transfers thevibrations 105 between the adjacent building elements. In some implementations, a special mechanical joint can be incorporated into one or more building elements in thetoy construction system 100 to enable the mechanical transmission of thevibrations 105 from any one of the building elements to another building element. - For example, with reference to
FIGS. 12A-12D and 13A-13D, one particular joint is a male and female dovetail; in which themale dovetail 1218 is formed on thebuilding element 1221 and thefemale dovetail 1319, which interfits with themale dovetail 1218, is formed in thebuilding element 1322. The joint can be formed into the building elements by injection molding. - Referring to
FIG. 14A , a close-up of one of thebristles 275 is shown fixed or constrained to thesecond element 273 and in theneutral position 201. As discussed above, thebristles 275 can be set at an acute angle relative to theneutral position 201; the angle selected determines how thesecond element 273 will move in response to thevibrations 105 imparted to thefirst element 271. Thus, as shown inFIG. 14B , thebristle 275 is at an angle Θ1 from theneutral position 201 and as shown inFIG. 14C , thebristle 275 is at an angle Θ2 from theneutral position 201. The angle selected can be any value from 0° (at the neutral position 201) just below 90° (which is close to being flat against the surface of the second element 273). Additionally, as discussed in more detail below with respect toFIGS. 15A-15C , 16, and 17, themotion converter apparatus 170 can includebristles 275 having variable angles to achieve different results in the motion produced at thesecond element 273. - The length LB of the
bristles 275 can be selected based on the geometry of themotion converter apparatus 170, and also can be selected based on the desired motion to impart to thesecond element 273. Thus, for example, as shown inFIG. 14D , a shorter length LB for thebristles 275 could impart a slower (low speed) motion or a shorter distance of motion to thesecond element 273 while, as shown inFIG. 14E , a longer length LB for thebristles 275 could impart a faster (high speed) motion or a longer distance of motion to thesecond element 273. Moreover, thebristles 275 of themotion converter apparatus 170 can be designed to have variable lengths, to achieve different results in motion produced at thesecond element 273. - Moreover, while the
bristles 275 can have a linear or straight geometry (as shown inFIG. 14A ) when in the neutral position 201 (and when not receiving any force from the first element 271), other geometries for thebristles 275 can be used either alone or in combination with linear geometries. For example, thebristles 275 can have a non-linear geometry, such as the curved geometry shown inFIG. 14F , when in theneutral position 201 and when not receiving any force from thefirst element 271. - In some implementations, the angles, geometries, and the lengths of each of the
bristles 275 of themotion converter apparatus 170 can be identical to each other. However, it is possible to use different or variable angles, different or variable lengths, and different or variable geometries for thebristles 275 in a singlemotion converter apparatus 170. - Additionally, while we have described bristle 275 arrangements that have simple geometric shapes such as circles and rectangles, which are easily described using mathematics, the arrangement of
bristles 275 could be non-geometric or complex geometries (which would not be easily described using mathematics). Additionally, the arrangement ofbristles 275 could be selected or designed to produce a sequence of unidirectional motions or a random, non-vibratory motion. - Referring to
FIGS. 15A-15C , an exemplary circular arrangement of bristles 1575 is shown in its natural environment (thus, thefirst element 271 is not applying any force to the bristles 1575). The arrangement includes three sets of bristles, 1575A, 1575B, and 1575C, with each set being on a concentric circle having a distinct radius and all of the bristles of every set being constrained by the motion of the monolithic second element 1573 (or themonolithic plate 1595 if a plate is used). The bristles inset 1575A are naturally slanted at an angle ΘA, the bristles inset 1575B are naturally slanted at angle ΘB, and the bristles inset 1575C are naturally slanted at angle ΘC, these angles given relative to theneutral position 1501, which is shown going into the page inFIG. 15A . Thus, for example, the angle ΘA is greater than the angle ΘA, which is greater than the angle ΘC. By adjusting the angle at which the bristles 1575 of the arrangement are naturally set, the motion imparted to thesecond element 273 can be adjusted, for example, to impart the motion more efficiently to thesecond element 273. - Referring to
FIG. 16 , another exemplary circular arrangement of bristles 1675 is shown in its natural environment (thus, thefirst element 271 is not applying any force to the bristles 1575). The arrangement includes three sets of bristles, 1675A, 1675B, and 1675C, with each set being on a concentric circle having a distinct radius and the bristles of each set being constrained by the motion of a respective partition orsegment segment sets sets segment 1673A could move more slowly than thesegments segment 1673B along aunidirectional path 1681B that is the opposite to thepaths respective segments FIG. 16 ). - Referring to
FIG. 17 , this concept of a segmented bristle arrangement and a corresponding segmented second element can be applied to a rectangular geometry. In this case, the bristles 1775 are segmented intosets second element segments unidirectional motion 1780 to the rectangular bristle/second element geometry. - Referring to
FIGS. 18A-C , in another implementation, thevibration speaker 110, thesupport building element 165, thecontrol system 130, the one ormore switches 140, and theenergy source 135 can be configured within an exemplary self-contained apparatus 1885 (or building element apparatus), in which omni-directional vibrations can be transmitted to permit the vibrations to be transferred from more than one surface of theapparatus 1885, for example, from two distinct and opposite surfaces, as described next. The vibrations are produced in all three dimensions because theapparatus 1885 is rigidly fixed to thebase 1855 of thevibration speaker 1810. - In this example, the
support building element 1865 and thevibration speaker 1810 are fixedly secured to thebuilding element base 1888, which houses thecontrol system 130 and the energy source 135 (not shown inFIG. 18A ). For example, thebase 1855 of thevibration speaker 1810 can be firmly mounted to thesupport building element 1865, and thesupport building element 1865 can be firmly mounted or fixed to thebuilding element base 1888 of theapparatus 1885. Thebuilding element base 1888 includes one ormore coupling mechanisms 1889 such as recesses for interconnecting with other building elements of the construction set 117. - Thus, in this particular implementation and to contrast with the implementation described in
FIG. 4B , thevibration speaker 1810 and thesupport building element 1865 are not suspended to freely move relative to thebuilding element base 1888. In this way, thevibrations 105 from thevibration speaker 1810 are freely transmitted along all directions outward to the outer surfaces of theapparatus 1885. Thus, the vibrations can be transmitted in an upward direction to thesupport building element 1865 and to any building element attached to thesupport building element 1865, as discussed previously. Moreover, thevibrations 105 from thevibration speaker 1810 are also freely transmitted along a downward direction to thebuilding element base 1888 and to any building element to which thebuilding element base 1888 is attached. - In this example, the
building element base 1888 is connected to aplate 1883, and theplate 1883 can be attached toisolator devices isolator devices plate 1883 from being imparted to any item on which theplate 1883 is placed. Moreover, the vibrations imparted to theplate 1883 can be transferred to other building elements (such as element 1871) attached to a top side of theplate 1883 that are remote from theapparatus 1885. - Other implementations are within the scope of the following claims.
Claims (14)
1. A toy construction system comprising:
a plurality of interconnectible building elements;
a control system that generates an electromagnetic signal;
a vibration speaker including:
a permanent magnet that is moveable;
a coil positioned near the permanent magnet and moveable relative to the permanent magnet, the coil configured to receive the electromagnetic signal from the control system such that the coil, the permanent magnet, or both vibrate in a manner that is based on the electromagnetic signal; and
a sound producer including a diaphragm that is mechanically linked to the coil to vibrate with the coil as the coil vibrates; and
a building element apparatus that houses the vibration speaker and is mechanically linked to the permanent magnet of the vibration speaker;
wherein:
the coil vibrates relative to the permanent magnet when the electromagnetic signal includes frequencies within a first frequency range, the vibration of the coil causing the diaphragm to vibrate and produce an audible sound, and
the permanent magnet vibrates when the electromagnetic signal includes frequencies within a second frequency range, the vibration of the permanent magnet causing the building element apparatus to vibrate.
2. The system of claim 1 , wherein the building element apparatus comprises:
a top surface including coupling mechanisms; and
a bottom surface including coupling mechanisms; and
both the top surface and the bottom surface are caused to vibrate due to the vibration of the permanent magnet.
3. The system of claim 1 , further comprising one or more vibration isolator devices each having a coupling mechanism that mates with the coupling mechanisms of the building element apparatus.
4. The system of claim 1 , wherein the building element apparatus and the vibration speaker are mechanically and fixedly linked together.
5. The system of claim 4 , wherein the vibration speaker comprises a base on which the permanent magnet is moveably mounted, the building element apparatus and the vibration speaker base being fixed together.
6. The system of claim 1 , further comprising a bristle module including a bristle pad positioned between a first building element and a second building element, the first building element connectible to the building element apparatus,
wherein the vibration of the building element apparatus causes the first building element to vibrate, the vibration of the first building element is converted into a unidirectional movement of the second building element by way of the bristle pad.
7. The system of claim 6 , wherein the bristle pad comprises a plurality of slantable bristles extending below a plate, the plate sized to fit within an opening of the second building element and the bristles resting on a top surface of the first building element.
8. The system of claim 6 , wherein the control system is within the building element apparatus.
9. The system of claim 1 , wherein the building element apparatus includes a platform building element.
10. The system of claim 1 , wherein the building element apparatus completely encloses the vibration speaker.
11. A toy comprising:
a control system that generates an electromagnetic signal;
a building element apparatus having coupling mechanisms on at least two exterior surfaces of a housing, the coupling mechanisms for connecting to building elements of a toy construction system, the building element apparatus housing containing a vibration speaker, the vibration speaker including:
a permanent magnet that is moveable relative to a base;
a coil positioned near the permanent magnet, the coil moveable relative to the permanent magnet, the coil configured to receive the electromagnetic signal from the control system such that both the coil and the permanent magnet vibrate at the same time in manners that are based on the frequencies of the electromagnetic signal; and
a sound producer including a diaphragm that is mechanically linked to the coil to move with the coil as the coil moves; and
a toy component that is mechanically linked to the permanent magnet;
wherein the simultaneous vibration of the diaphragm and the permanent magnet causes the simultaneous vibration of the at least two exterior surfaces of the building element apparatus, movement of the toy component, and the production of audible sound that complements the toy component movement.
12. The toy of claim 11 , wherein the at least two exterior surfaces of the building element apparatus comprise at least two opposite sides of the building element apparatus.
13. The toy of claim 12 , wherein the at least two opposite sides of the building element comprise a top side of the building element and a bottom side of the building element.
14. The toy of claim 11 , wherein the simultaneous vibration of the diaphragm and the permanent magnet causes the housing of the building element apparatus to vibrate in a plurality of directions.
Priority Applications (1)
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US13/899,490 US20160296849A9 (en) | 2012-05-22 | 2013-05-21 | Building Elements with Sonic Actuation |
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US13/477,944 US8911275B2 (en) | 2012-05-22 | 2012-05-22 | Building elements with sonic actuation |
US13/899,490 US20160296849A9 (en) | 2012-05-22 | 2013-05-21 | Building Elements with Sonic Actuation |
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US13/477,944 Continuation-In-Part US8911275B2 (en) | 2012-05-22 | 2012-05-22 | Building elements with sonic actuation |
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US20170282090A1 (en) * | 2016-03-30 | 2017-10-05 | Fujitsu Limited | Construction toy with programmable connectors |
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USD872807S1 (en) * | 2018-05-17 | 2020-01-14 | ARK Therapeutic Services, Inc. | Fidget spinner |
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DK3917634T3 (en) * | 2019-01-31 | 2024-04-22 | Lego As | TOY SYSTEM WITH A NON-CONTACT ENERGY TRANSFER SYSTEM |
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US11207607B2 (en) | 2009-07-15 | 2021-12-28 | May Patents Ltd. | Sequentially operated modules |
US9559519B2 (en) | 2009-07-15 | 2017-01-31 | Yehuda Binder | Sequentially operated modules |
US10589183B2 (en) | 2009-07-15 | 2020-03-17 | May Patents Ltd. | Sequentially operated modules |
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US20150251104A1 (en) * | 2012-09-03 | 2015-09-10 | Kinematics Gmbh | Connection structure between building blocks and building blocks connected therewith |
US20170282090A1 (en) * | 2016-03-30 | 2017-10-05 | Fujitsu Limited | Construction toy with programmable connectors |
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