BR102012008845A2 - toy vehicle track assembly, and, toy vehicle impeller coupled to a track - Google Patents

Abstract

TOY VEHICLE TRACK ASSEMBLY, AND TOY VEHICLE IMPULSOR COUPLED TO A TRACK. A pusher mechanism which can be rolled or loaded for successive impulses of toy vehicles is disclosed. The pusher mechanism includes multiple spaced pusher arms that engage toy vehicles that activate the pusher mechanism.

Description

“TOY VEHICLE TRACK ASSEMBLY, AND TOY VEHICLE DRIVER COUPLED TO A TRACK”

CROSS REFERENCE TO RELATED APPLICATION

This application claims priority for US Patent Application No. 61 / 475,997, and is based thereon, filed April 15, 2011, entitled "Booster Mechanism for Toy Vehicle Track Set", the full disclosure of which is incorporated herein by reference. .

FIELD OF THE INVENTION The present invention relates to a pusher mechanism for a toy vehicle track assembly and, in particular, a rollable pusher mechanism with multiple engaging portions or pusher arms that can continuously pusher toy vehicles.

BACKGROUND OF THE INVENTION Some driving mechanisms are known in the art. Some conventional impellers are manually activated by a child. In such impellers, a child attempts to manipulate a trigger at the appropriate time to engage a passing toy vehicle to provide momentum to the toy vehicle. For such a driving mechanism, a child has to be involved with each thrust of a toy vehicle.

There is a need for a drive mechanism that can be loaded for multiple uses. There is also a need for a thruster mechanism that can propel consecutive toy vehicles without user interaction.

SUMMARY OF THE INVENTION The present invention is directed to a toy vehicle track assembly that includes a track along which toy vehicles may travel, and a pusher mechanism coupled to the track, the pusher mechanism including a body mounted for full rotation in about an axle, the body including a plurality of pusher arms, each of which is configured to engage a toy vehicle, the body being rollable against a push mechanism to a loaded position such that each time the pusher mechanism is activated by a toy vehicle, the body pivots a partial rotation about the shaft out of the loaded position so that one of the push arms engages and pushes the active toy vehicle.

The present invention is also directed to a toy vehicle impeller coupled to a closed loop track. The pusher includes a base portion, a rotationally coupled pusher element in the base portion, the pusher element being configured to move 360 degrees relative to the base portion, the pusher element including a plurality of engaging portions, each of the pivot portions. coupling being configured to engage a toy vehicle, and an alignment mechanism coupled to the pusher element, the alignment mechanism allowing the pusher element to rotate only a partial rotation repeatedly in response to activation of the pusher by sequential toy vehicles.

The present invention is also directed to a toy vehicle impeller coupled to a closed loop track. The pusher includes a base portion, a rotationally coupled pusher member in the base portion, the pusher member being configured to move 360 degrees relative to the base portion, the pusher member including a plurality of engaging portions, a coupled request member at the pusher element, the biasing element predisposing the pusher element to a resting position, and a tongue engaging the pusher element to stop the pusher element during its rotation after activation by a toy vehicle so that the pusher element rotates only one partial rotation.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 illustrates a perspective view of a pair of push-on toy vehicle tracks in accordance with the present invention.

Figure 2 illustrates a close up perspective view of a portion of one of the toy vehicle tracks illustrated in Figure 1.

Figures 3-5 illustrate different top perspective views of some of the toy vehicle track components shown in Figure 2 in different disassembly states.

Figure 6 illustrates a bottom perspective view of the

pusher mechanism illustrated in figure 2.

Figure 6A illustrates a bottom perspective view of some components of the pusher mechanism illustrated in Figure 2 in a disengaged configuration.

Figure 6B illustrates a bottom perspective view of the

pusher mechanism components shown in Figure 6A in a engaged configuration.

Figure 6C illustrates an inverted side view of the components shown in Figures 6A and 6B in a locked configuration.

Figure 6D illustrates an inverted side view of the

components illustrated in figure 6C in a released configuration.

Figure 7 illustrates a top perspective view of another embodiment of a toy vehicle track in accordance with the present invention and illustrated in Figure 1.

Figure 8 illustrates a top perspective view of the

pusher mechanism illustrated in figure 7 in a disassembly state.

Figure 8A illustrates a top view of a pusher ratchet mechanism illustrated in Figure 8.

Figures 9-11 illustrate different top perspective views of the pusher mechanism illustrated in figure 7 in different disassembly states.

Fig. 12 illustrates a bottom perspective view of the pusher mechanism illustrated in Fig. 7 with various disassembled components.

Figures 12A and 12B illustrate views showing relative motions of the driver portion of the pusher mechanism illustrated in Figure 7.

Figure 13 illustrates a bottom perspective view of the pusher mechanism shown in Figure 7 with various disassembled components.

Figure 14 shows a perspective view of another embodiment of a pusher mechanism for a toy vehicle track in accordance with the present invention.

Figure 15 shows a perspective view of yet another embodiment of a pusher mechanism for a toy vehicle track in accordance with the present invention.

Equal reference numbers were used to identify equal elements throughout this disclosure.

DETAILED DESCRIPTION OF THE INVENTION

A pusher mechanism according to the present invention includes at least one pusher arm or hitch portion that can be moved to engage a toy vehicle on a toy vehicle track assembly. When the pusher arm moves while in contact with the toy vehicle, a force is applied to the toy vehicle along the direction of the track that moves or propels the toy vehicle along the track. In one embodiment, the pusher mechanism includes a rotatable body with three pusher arms that are equally spaced.

The pusher mechanism also includes a drive mechanism which may alternatively be referred to as a winding or winding mechanism. The drive mechanism includes a request element that can be wound to generate potential energy in the request element. A child can wrap the request element, which is held in a loaded setting or condition until released.

The pusher mechanism includes a driver that is engaging by a toy vehicle on the track. The actuator has a portion that prevents the rotating body of the pusher mechanism from moving. When the actuator is engaged by a passing toy vehicle, the actuator moves to a release or released position that releases the rotating body. In one embodiment, the rotary body rotates part of a complete rotation, such as 120 °, until the driver engages the rotary body and prevents further movement. These release, move, and lockout steps repeat for each passing toy vehicle that activates the trigger until the potential energy in the request element runs out.

Referring to Figure 1, two sets of toy vehicle tracks or tracks according to the present invention are illustrated. Each of the track assemblies includes a pusher mechanism that is used to propel or propel a toy vehicle along the track. Since each of the track assemblies is a closed loop track, a toy vehicle that is driven moves along the track from one end to the other end and returns to the driving mechanism to be driven again.

As shown in Figure 1, the toy vehicle track 10 includes a pusher mechanism 100 and the toy vehicle track 500 includes a pusher mechanism 600. The toy vehicle track assembly 10 is illustrated and discussed with respect to figures 1 -6, and 6A-6D. Toy vehicle track assembly 500 is illustrated and discussed with reference to Figures 1 and 7-8, 8A, 9-12, 12A, 12B and 13. Track 10 and 500 assemblies have several similar features discussed below. Referring to Figure 1, the toy vehicle track assembly 10 includes a closed loop track 20 with opposite ends 22 and 24. Track 20 is inclined from end 22 to end

24 and held in that position or orientation via various brackets 26. The tilt angle facilitates the return of a toy vehicle from end 24 to end 22, where the pusher mechanism 100 is located. The lane 20 includes a portion of the lane 30 which includes a channel 32 which is formed by opposite side walls and along which a toy vehicle may travel.

Referring to Figure 2, a top perspective view of a portion of runway 20 and pusher mechanism 100 is shown. Next to runway 20 is a base or base portion 110 having an upper surface 112 and a lower surface 114 (see figure 6). In one embodiment, the base 110 may be formed separately from the runway 20 and placed in or near the runway 20. In another embodiment, base 110 may be formed integrally with runway 20.

Lane 20 includes a curve 34 along which toy vehicles may travel. Coupled to curve 34 is a guard 50, which may be a piece of plastic formed integrally with curve 34, or separately formed and subsequently coupled therein. Guard 50 reduces the likelihood that a driven toy vehicle will be lifted off lane 20 through curve 34. Pusher mechanism 100 is located near curve 34 and a portion of the pusher arms of pusher mechanism 100 extends within the curve. 34 of lane 20 to engage a toy vehicle passing along curve 34.

In this embodiment, the pusher mechanism 100 includes a body 120 having multiple engaging portions. The body 120 is rotationally mounted to the base 110 and can rotate in a complete circle. Multiple coupling portions allow the impeller to rotate or incrementally advance in a particular direction and propel successive toy vehicles.

Extending from the body 120 are pusher arms or arms 130, 140, and 150, which may also be referred to as engaging portions. Each arm 130, 140 and 150 has a longitudinal axis along which the arm extends. Each longitudinal axis, and the corresponding arm, is 120 ° spaced from the other two adjacent axes and arms.

As shown in Figure 2, arm 130 includes a finger or engaging member 132 that provides a larger surface area with which a toy vehicle makes contact with only the side edge of arm 130. In this embodiment, the engaging member 132 has a flat contact surface that engages a rear surface of the toy vehicle. The engaging member 132 may be formed integrally with the rest of the arm 130 or alternatively may be formed separately from the rest of the arm 130 and subsequently coupled thereto.

Similarly, arm 140 includes a finger or engaging member 142 with a flat contact surface 144 (see figure 3) and arm 150 includes a finger or engaging element 152 with a flat contact surface 154 (see figure 3). In one embodiment, body 120 and arms 130, 140 and 150 may be integrally formed. In another embodiment, body 120 and arms 130, 140 and 150 may be formed separately and arms coupled to body 120.

As described below, the body 120 of the pusher mechanism 100 has an initial resting or undisposed position relative to the base 110. The body 120 may move against the force of a biasing element to a loaded or coiled and held position. in this position via a latch or latch. When the latch or latch is released, the biasing member may prompt the body 120 to rotate and engage a passing toy vehicle. The body 120 will continue to rotate as long as the biasing element forces a force on the body 120 and as long as the latch or latch is not in a locking or engaging position.

The pusher mechanism 100 includes a drive mechanism 250, which may alternatively be referred to as a winding or loading mechanism, which may be manipulated by a user to load or wind the pusher mechanism 100. In this embodiment, the loading or winding mechanism 250 includes a crank 260. A user may rotate crank 260 and, as a result, body 120 along the direction of arrow “A” around a mechanical axis 116 defining a rotation axis 125. Crank 260 is engaged It is a portion of the sleeve 262 and has a support 270 which contacts a locking member 280 to wind the inner spring in the portion of the sleeve 262 as the handle 260 is turned or driven. The coupling element 280 is also part of the clutch mechanism that prevents overwinding of the crank 260 and protects the biasing element or spring, which is discussed in detail below.

In this embodiment, the pusher mechanism 100 includes a driver, a portion 430 of which extends above the displacement surface of the toy vehicle track. In one embodiment, driver portion 430 is located along curve 34. When impeller body 120 rotates to drive toy vehicles, body 120 rotates along the direction of arrow “B” around axis 125.

Referring to Figure 3, the components of the pusher mechanism 100, including the body 120 and the winding mechanism 250, have been removed from the base 110. As shown, the upwardly extending mechanical shaft 116 of the base 110 is of sufficient length. such that the body 120 and the winding mechanism 250 may be rotationally mounted therein. Each of the body 120 and winding mechanism 250 includes an opening or bore that is configured to receive the mechanical shaft 116. The body 120 has an upper surface 124 (see figure 3) and an opposite lower surface 126 (see figure 5). .

Referring again to Figure 3, in this embodiment, the pusher mechanism 100 includes a protrusion 282 extending above the winding mechanism 250. The protrusion 282 includes a notch 284 formed on its upper surface. The notch 284 is sized to receive a portion of the engaging member 280. As the crank 260 rotates and the bearing 270 contacts the engaging member 280, the movement of the engaging member 280 causes the protrusion 282 to rotate equally. .

Also shown in Fig. 3, as previously referenced, are the contact surfaces 144 and 154 of the pusher arms 140 and 150, respectively. In this embodiment, the contact surfaces 144 and 154 are generally flat. In other embodiments of the invention, contact surfaces 144 and 154 may be textured and / or have a non-flat shape or configuration.

Referring to FIG. 4, the winding mechanism 250 is illustrated separately from the body 120. The body 120 includes a central portion 122 and coupled to the upper surface 124 of the central portion 122 is a winding device 290 having several supports 294. which define slots or divisions 296 between adjacent supports 294. Located between all supports 294 is a central bore 292 through which the mechanical shaft 116 of base 110 can pass.

As shown, coupled to crank 260 is a jacket 262 which has a wall 264 defining a receptacle 266. Wall 264 also includes a slot 268 formed therethrough. In this embodiment, crank 260 and liner 262 are integrally formed.

A biasing element 300, such as a coil spring, has opposite ends 302 and 304 and is located in receptacle 266. Because of the coiled spring configuration 300, end 302 is an inner end and end 304 is an outer end of the spring. spring 300. End 304 extends through slot 268 as shown. End 302 of spring 300 is disposed between one or more of slots 296 between supports 294. End 302 is retained in one or more of slots 5 296 because of friction and, in some cases, by stapling or folding of end 302. .

Winding device 290 is used for winding the spring.

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300. As crank 260 is rotated, crank 260 rotates relative to body 120. As end of biasing member 10 302 is coupled to winding device 290 in body 120, rotation of crank 260 moves the request element 304 end relative to request element 302. end. This relative movement causes the request element 300 to be wound and constrained around winding device 290. The length of the winding of request element 300 is limited to when the biasing element 300 is tightly wound on the winding device 290 and itself. When request element 300 is wound, it stores potential energy that is used to drive and rotate body 120 relative to base 110 and runway 20.

Referring to Figure 5, a view in

bottom perspective of the body 120 of the pusher mechanism 100. As shown, the body 120 has a lower surface or side 126 on which a plurality of tabs or stops are coupled. In this embodiment, the body 120 has three tongues 160, 170 and 180 which are equally spaced. The tongues 25 160, 170 and 180 collectively form part of an alignment mechanism that allows the body 120 to be indexed or incrementally rotated. Each of the tabs 160, 170 and 180 is positioned such that one of the pusher arms 130, 140 and 150 is in a loaded position ready to propel a toy vehicle when released (such as arm 140 in FIG. 2). The tongues 160, 170 and 180 are used to control the amount of rotation of the body 120 around the axis 125 as the biasing mechanism 300 unwinds. As the tongues 160, 170 and 180 are spaced 120 ° apart, the engagement of successive tongues by an actuator as described below results in rotation of the body 120 by approximately 120 °. This incremental or partial body rotation facilitates multiple toy vehicles to propel each full rotation of the rotary body 120.

The tongues 160, 170 and 180 have ferrules or projections 162, 172 and 182 respectively. Ferrules 162, 172 and 182 are oriented such that they engage a portion of a driver as described below. The tabs 160, 170 and 180 may be formed separately from the body 120 and subsequently coupled thereto using an adhesive or a connector, such as a screw. Alternatively, the tongues 160, 170 and 180 may be integrally formed with the body 120.

Referring to Fig. 6, a bottom perspective view of the pusher mechanism 100 and a portion of the track 20 is shown. As shown, the base 110 has a lower surface or lower side 114 that is oriented towards a support surface, and / or placed in contact with it, in which the track assembly 10 is placed. Coupled to base 110 is a driver 400 which is activated by a toy vehicle on track 20 and releases body 120 to rotate upon request of request member 300.

In this embodiment, driver 400 includes an elongate member 410 with opposite ends 412e414. The elongate member 410 may be a rod or link. Near end 412 is a locking portion 420 which engages the body 120 as shown. In Fig. 6, the engaging portion 420 is shown engaged with the latch 180. Next to the end 414 is a protruding portion 430 (see Fig. 2) extending to the path of runway 20 through an opening formed in runway 20. elongate member 410 is coupled to track 20 and / or base 110 and is mounted for at least partial rotation about its longitudinal axis 425. A biasing mechanism, such as a spring, is positioned to bias elongate member 410 for a starting position where the projecting portion 430 extends to the runway channel or area 20.

When a toy vehicle makes contact with the projecting portion 430, the projecting portion 430 moves downward and the elongate member 410 rotates about axis 425 against the request of its requesting mechanism. Rotation of the elongate member 410 about axis 425 causes the engaging portion 420 to rotate equally. When the engaging portion 420 rotates from its locked or locked position shown in FIG. 6, body 120 rotates until the next latch stops by the engaging portion 420.

Referring to FIGS. 6A-6D, the interaction of driver 400 and tongue 180 is illustrated. Each of FIGS. 6A-6D is an inverted view of some of the components of the pusher mechanism 100.

In this embodiment, the actuator 400 is biased by a biasing element, such as a spring, to a locking position 422. In this position, the engaging portion 420 of the actuator 400 is in a position in which it can engage one of the tongues 160. 170 or 180. As shown in Figure 6A, rotation of the body 120 moves the portion of the body 120 with tongue 180 along the direction of arrow "C". The tongue 180 with its tip 182 defines a notch 184 with which the engaging portion 420 engages as shown in Figure 6B. When the engaging portion 420 makes contact with the tongue 180, the rotation of the body 120 about the axis 125 is interrupted. Referring to Figure 6C, an end view of the components illustrated in Figures 6A and 6B is shown. Body 120 and tongue 180 move from a disengaged position 186 to a engaged position 188 as body 120 moves along the direction of arrow "Cl". Referring to Figure 6D, the engaging portion 420 is shown in its initial position 422 (shown in dashed lines) where

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it makes contact with the tongue 180. As the elongate member 410 rotates along the direction of the arrow "D", the engaging portion 420 moves about 5 of the axis 426 to its unlocked position 424. In this position 424 there is a gap 440 between hitch portion 420 and body 120. Slack 440 is sufficiently sized to allow latch 180 to move therethrough causing body 120 to rotate along the direction of the arrow "F \".

When the toy vehicle disengages from the trigger, the

elongate member 410 pivots about axis 426 along the direction of the arrow "F" from position 424 to position 422. Coupling portion 420 is thus positioned to make contact with the next pawl, such as pawl 160, and to stop the body 120 after it rotates 120 °.

Once the request mechanism 300 is wound, the

In a process where a toy vehicle activates driver 400, driver 400 moves to allow rotation of body 120, body 120 of pusher mechanism 100 rotates 120 ° about axis 125 and engages the toy vehicle, driver 400 to body rotation 120 repeats with each successive actuation by a toy vehicle until the potential energy stored in the request mechanism runs out. In one implementation, the winding mechanism 250 may be rotated or driven seven times, which allows the body 120 to make seven complete revolutions because of the potential energy in the winding request mechanism 300. The body 120 may propel twenty-one vehicles. in a row as toy vehicles continuously activate driver 400 per lane assembly 10.

Referring again to Figure 1, the toy vehicle track assembly 500 includes a closed loop track 510 with opposite ends 512 and 514. Track 510 is similarly inclined from end 512 to end 514 and held in this position via brackets 516. and a base support 518 (see figure 7). Pusher mechanism 600 is located near end 512 of track 510.

Referring to Figure 7, a portion of track 510 and pusher mechanism 600 are illustrated. Similar to pusher mechanism 100, pusher mechanism 600 includes a drive mechanism 700, which may be referred to as a winding or loading mechanism. In this embodiment, track 510 includes a curve 520 along which an arm of the pusher mechanism 600 travels to propel a passing toy vehicle. Lane 510 includes a guard 530 with a projecting portion 532 located near where a pusher arm initially engages a toy vehicle. The guard 530 is coupled to a frame 534 which has several pillars 536 extending therefrom. In one embodiment, the guard 530 is transparent, which allows a child to see the drive mechanism 600 engaged in a toy vehicle.

Lane 510 includes a base 540 coupled to or formed therein. Base 540 rotatably supports pusher mechanism 600. Lane 510 includes an outer wall 550 which has several spaced brackets 552 with openings 554 into which pillars 536 may be inserted to engage guard 530 in track 510.

Referring to Figures 8 and 9, some of the components of the pusher mechanism 600 are illustrated. In this embodiment, the pusher mechanism 600 includes a body 620 with an upper surface 624 and arms 630, 640 and 650, each of which is spaced 120. °.

In this embodiment, the pusher mechanism 600 includes a loading or winding mechanism 700 that can be manipulated by a child to wind the pusher mechanism 600. As shown in figure 8, the winding mechanism 700 includes a lid 720 having a wall 722 with teeth 724 formed along an inner surface. Wall 722 defines a receptacle 726 and lid 720 includes a centrally located hole 728.

The winding mechanism 700 includes a crank 710 which is coupled to a body 712 with an upper surface 713 on which a ratchet mechanism 740 is mounted. The body 712 also includes a hanging wall 714 defining a receptacle 716 (see figure 9).

Referring to Figures 8 and 8A, components of ratchet mechanism 740 are shown. As shown, ratchet mechanism 740 includes a pair of cam elements 750 and 760. Cam elements 750 and 760 include mounting holes 756. and 766 through which connectors 770 and 772 are inserted to pivot mount cam members 750 and 760 to body 712 coupled to crank 710. As shown in FIG. 8A, each of cam elements 750 and 760 includes opposite ends 752, 754 and 762, 764 and a motion bore 757 and 767, respectively.

A biasing element 780, such as a resilient tape, couples the cam elements 750 and 760 together. Biasing member 780 extends around pillars 715 and 717 which are formed on upper surface 713 of body 712. Biasing member 780 biases cam member 750 around connector 770 in bore 756 along the direction of arrow "G." Similarly, biasing element 780 biases cam element 760 around connector 772 into bore 766 along the direction of arrow "H." The result of biasing cam elements 750 and 760 in these directions is that the distal tips or ends 752 and 762 of the elements 750 and 760 are forced outward to engage with the inner surface of the lid 720 wall 722. The tips 752 and 762 engage the teeth 724 of lid 720, which results in the translation of rotation of crank 710 in rotation of winding mechanism 700.

Referring to Figure 9, the winding mechanism 700 also includes a winding device 790 having a center pillar 792 and brackets 794 located near the center pillar 792. Slots or gaps 796 are formed between the pillar 792 and the brackets 794. The winding mechanism 700 also includes a biasing element or mechanism 5 800, such as a coil spring, with opposite ends (only inner end 802 is shown in figure 9). Biasing member 800 is located in receptacle 716 of crank portion 710 and inner end 802 is disposed in one or more of slots 796. The other end of biasing member 800 is fixed to crank 710 such that the rotation of crank 710 move the other end. As a result, as request element 800 unwinds, request element 800 transfers motion to body 620 because of the connection between request element 800 and body 620.

Referring to FIG. 10, base 540 includes a mechanical pillar or shaft 546 extending from upper surface 542. A slot 548 is formed next to pillar 546. An anvil 942 of a driver 900 is illustrated extending through 548. Stop 942 moves along the directions of arrow "I." Details of the stop are discussed in more detail below.

Referring to Figure 11, a base view of the

body 620. Body 620 includes a lower surface 626 to which a plurality of latches are coupled. As shown, the lugs 660, 670 and 680 are coupled to the bottom surface 626 via connectors such as screws extending through the lugs 660, 670 and 680. Each of the lugs 25 660, 670 and 680 includes one end or ferrule 662, 672 and 682, respectively. Tabs 660, 670, and 680 are spaced 120 ° in the same configuration as tabs 160, 170, and 180 for the above-described track assembly 10.

Referring to Figures 12, 12A, 12B and 13, details of driver 900 of track assembly 500 are illustrated. In this embodiment, base 540 has a lower surface 544 with a cavity or chamber 545. A cover plate 570 may be be coupled to base 540 to cover cavity 545. cover plate 570 has several openings 572 through which connectors 574, such as screws, can be inserted to be connected to openings formed in mounting structures in. cover plate 570 may be coupled to base 540 to cover cavity 545. As shown in Figure 12, runway 510 includes a slot 560 extending through runway 510 between the upper and lower surfaces of runway 510. .

In this embodiment, driver 900 includes an elongate member 910 with opposite ends 912 and 914. Near end 912 is a locking member 930 and near end 914 is a latch member or latch 940. Elongate member 910 is coupled or mounted on base 540 and is rotatable about its longitudinal axis 915.

Referring to Figure 13, a plurality of notched end supports are spaced apart and used to position elongate member 910. Bracket 921 is located to engage elongate member 910 near end 912. Brackets 923 and 925 are located to engage elongate member 910 near end 914.

As shown in Figure 13, elongate member 910 has a collar or shirt 920 which has a groove formed therein. Collar 920 is positioned in engagement with bracket 921 and bracket 921 engages the groove. Similarly, the elongate member has necklaces 922 and 924 near end 914. Necklaces 922 and 924 engage brackets 923 and 925, respectively, and have grooves that receive ends of brackets 923 and 925. Grooves in necklaces 920, 922 and 924 extend at the perimeter of the collars and allow rotation of the collars 920, 922 and 924 relative to the brackets 921, 923 and 925. The inner surface of the cover plate 570 has brackets corresponding to brackets 921, 923 and 925, and they are aligned with them when the cover plate 570 is coupled to base 540. The different support assemblies capture the corresponding collar from necklaces 920, 922, or 924 between them.

As previously mentioned, the elongate member 910 is mounted for rotation about shaft 915. Figure 12A illustrates the movement of the engaging member 930 as the elongate member 910 rotates and Figure 12B illustrates the movement of the tongue portion 940 to as the elongate member 910 rotates. Each of the engaging member 930 and the tongue portion 940 is fixed to the elongate member 910. As a result, movement of any of the components.

Referring to Figure 12A, a toy vehicle 1000 travels along track 510 in the direction of arrow "J," which is also illustrated in Figure 12. As toy vehicle 1000 moves in this direction, a portion of the toy vehicle 1000 makes contact or engages a contact surface 933 on an upper portion 932 of the engaging member 930. The engaging member 930 has an initial or predisposed position 934 in which the engaging member 930 is positioned without any applied force in the engaging member 930. A biasing element, such as a spring, is provided for biasing the elongate element 910 and thus the engaging member 930 for this orientation. When toy vehicle 1000 makes contact with surface 933, the engaging member 930 moves within slot 560 and pivots about axis 915 along the direction of arrow “K.” As a result, the engaging member 930 moves to a contact position 936 (shown in dashed line) and elongate member 910 rotates about axis 915 equally. When the force of the toy vehicle 1000 is no longer applied to the contact surface 933, the engaging member 930 returns to its initial or predisposed position 934.

Referring to Figure 12B, the tongue portion 940 located at the opposite end of the elongate member 910 relative to the engaging member 930 also moves. The latch portion 940 has a protruding portion 942 that extends upward through slot 548 in base 540 (see Figures 10 and 13) when the latch portion 940 is in its locking position 944. In this position 944, the portion protruding 942 contacts or engages one of the latches 660, 670, and 680 on the rotatable body 620. When the engaging member 930 rotates about axis 915 along the direction of the arrow "K," the latch portion 940 also rotates around shaft 915 along the direction of arrow "L" to an unlocking position 946, which allows the latch to move past the protruding portion 942. Body 620 rotates until the next latch engages the latch portion 940 of the actuator. 900. This process is repeated until the request element has insufficient potential energy to cause the body 620 to rotate incrementally any further.

Referring to Fig. 14, a perspective view of another embodiment of a track assembly is illustrated. In Figure 14, only the curve portion of lane 1170 and pusher mechanism 1100 are illustrated. Lane 1170 has connectors 1172 and 1174 that facilitate connection of lane 1170 with other lane pieces that may be of any shape or shape.

Lane 1170 has a base portion 1105 integrally formed therewith. The pusher mechanism 1100 is rotationally mounted to the base portion 1105 and includes a rotary body 1110 with several pusher arms or engaging portions 1120, 1130 and 1140. In this embodiment each arm includes a contact surface which may be coated with a material to reduce the impact of the arm on the toy vehicle. For example, the arms may include a rubber coating or similar material as shown by surfaces 1132 and 1142 of arms 1130 and 1140, respectively. The pusher mechanism 1100 includes a winding mechanism 1150 with a crank 1152 that can be used to wind a spring that is internally located in the winding mechanism 1150. Referring to Figure 15, a perspective view of a fourth embodiment is illustrated. A track set. The toy vehicle track assembly 1500 includes a closed circuit track 1510 with opposite ends 1512 and 1514 which may each be circular, but, unlike the foregoing embodiments, the first end 1512 may be oriented as a substantially vertical circuit. The two ends 1512 and 1514 may be connected to each other at intersection 1570, and the lane portions 1510 may be supported by brackets 1516 so that lane 1510 is inclined from intersection 1570 to end 1514. Similar to lane 20 of a In the prior embodiment, the tilt angle facilitates the return of a toy vehicle 2000 from end 1514 to end 1512 where the pusher mechanism 1600 is located. Lane 1510 includes a channel 1532 which is formed of opposite side walls and along which a toy vehicle may travel. In one embodiment, lane 1510 includes a repositionable portion 1580 that can move relative to intersection 1570 to create various game configurations. For example, portion 1580 may be positioned such that a toy vehicle 2000 traveling along it jumps over intersection 1570, thereby avoiding collisions with another toy vehicle 2000.

Referring to FIG. 15, the track assembly 1500 also includes a base 1540. A base 1540 supports the impeller 1600 in a vertical orientation while receiving a portion of track 1510. In some embodiments, such as the embodiment shown in FIG. 15 , a curve 1520 is supported or included in a portion of an outer wall 1550 of base 1540, such that curve 1520 may be engaged by vertically oriented impeller 1600. Thus, outer wall 1550 of track 1500 is at least a portion of a vertically oriented annular crown such that the outer wall 1550 provides a circuit or ring for the pusher mechanism 1600 to rotate. The outer wall 1550 also includes openings 1554 so that toy vehicles may enter and exit base 1500 and brackets 1552 so that base 1500 may be mounted on a pre-existing track 1500. Additionally, a loading or winding mechanism 1700 may be mounted on the impeller 1600 such that any winding may occur about the central axis of the annular outer wall 1550.

Also shown in Figure 15 is the pusher mechanism 1600 including arms 1630, 1640 and 1650, each including a coupling portion, 1662, 1672 and 1682, respectively. Each of the arms 1630, 1640 and 1650 may be coupled to or formed integrally with a body 1620 (see Figure 15) such that the arms 1630, 1640 and 1650 may rotate about the outer wall central axis 1550. still engaging at least one portion of curve 1520 alternately. Multiple engaging portions allow the impeller to rotate or incrementally advance in a particular direction and propel successive toy vehicles. In this particular embodiment, a vehicle 2000 may be driven in a substantially upward direction such that it has sufficient speed to traverse the vertical circuit included at end 1512.

In order to actuate the pusher mechanism, a user may wind up the winding mechanism 1700 and subsequently activate a driving mechanism 1900 (seen in figure 15). The winding mechanism may include a body that may be covered by the lid 1720, which may include an outer wall. Lid 1720 and the body may form a housing that can house any suitable energy storage mechanism (not shown). In order to transfer energy to this mechanism, a crank 1710 (seen in Figure 15) may be rotated about a central axis of the cover 1720. The winding mechanism may be operably coupled to the pusher mechanism such that energy is transferred to the mechanism. winding mechanism may be transferred to the pusher mechanism.

Once power has been transferred to the winding mechanism 1700, actuation of the actuation mechanism may cause

the impeller mechanism 1600 propels a toy vehicle. Actuating mechanism 1900 is included in base 1540 internally or externally and operably connected to both winding mechanism 1700 and pusher mechanism 1600, such that pusher mechanism 1600 can rotate one-third of a rotation (120 degrees) when the mechanism of actuation is acted. In this particular embodiment, an actuation element 1930 is included in base 1540 and protrudes from it such that it can be engaged by a vehicle 2000 traveling along track 1510.

In this embodiment, the track assembly 1500 includes one or more brackets for locating the pusher mechanism such that it engages at least a portion of the pivot 1510. In one embodiment, it is preferable to mount the pusher mechanism in a position that maximizes its engagement with the pivot. lane 1510. Winding mechanism 1700 may be mounted on the same axis as impeller mechanism 1600 to provide an efficient and aesthetic design. Therefore, in this embodiment, where impeller 1600 engages track 1500 in curve 1520, it is preferable to mount impeller mechanism 1600 and winding mechanism 1700 in the center of curve 1520. One or more supports support the impeller mechanism in one position while others brackets support the winding mechanism in a position like this.

In alternative embodiments, a pusher mechanism according to the present invention may include a rotary body with two pusher arms or with four or more pusher arms. For multiple pusher arms in a pusher mechanism, the pusher arms are equally spaced. The number of pusher arms determines the extent to which the rotating body rotates incrementally during each activation of the pusher mechanism. The drive arms may be of any material that provides sufficient force to a driven toy vehicle, such as a plastics material.

It should be understood that terms such as “left”, “right”, “top”, “base”, “front”, “end”, “rear”, “side”, “height”, “length”, “width” ”,“ Upper ”,“ lower ”,“ inner ”,“ outer ”,“ inner ”,“ outer ”and the like as used herein merely describe reference points or portions, and do not limit the present invention to any orientation or particular setting. Additionally, terms such as "first", "second", "third", etc., merely identify one of a number of portions, components and / or reference points disclosed herein, and do not limit the present invention to any particular configuration or orientation. .

Although the disclosed inventions are illustrated and described herein conceived in one or more specific examples, they are not intended to be limited to the details shown, however, since various modifications and structural changes can be made to them without departing from the scope of the inventions. For example, the drive arms of the rotary mechanism may engage a moving vehicle in a straight portion of the track. Moreover, various features of one embodiment may be incorporated into another embodiment. Accordingly, it is appropriate that the invention be interpreted broadly and in a manner consistent with the scope of the disclosure.

Claims (20)

Toy vehicle track assembly, characterized in that it comprises: a track along which a toy vehicle may travel; and a track-coupled pusher mechanism, the pusher mechanism including a body mounted for full rotation about an axis, the body including a plurality of pusher arms, each of the plurality of pusher arms is configured to engage a toy vehicle, body being rollable against a biasing mechanism to a loaded position such that each time the pusher mechanism is actuated by a toy vehicle, the body rotates a partial rotation about the shaft out of the loaded position such that one of the pusher arms engage and propels the acting toy vehicle. Toy vehicle track assembly according to claim 1, characterized in that the track forms a closed loop. Toy vehicle track assembly according to claim 1, characterized in that the track includes a bend and the pusher mechanism is coupled to the track near the bend so that each pusher arm can extend at least partially to the turn to engage and propel a toy vehicle around the turn. Toy vehicle track assembly according to claim 1, characterized in that the partial rotation is one third of one rotation. Toy vehicle track assembly according to claim 1, characterized in that the loaded position is a first loaded position and the body is configured to partially rotate from the first loaded position to a second loaded position when actuated. by a toy vehicle. Toy vehicle track assembly according to claim 5, characterized in that the body remains at least momentarily in the second loaded position until the pusher mechanism is again actuated by a toy vehicle. Toy vehicle track assembly according to claim 1, characterized in that the drive arms further include engaging elements that increase the contact area between the drive arms and an acting toy vehicle. Toy vehicle track assembly according to claim 1, characterized in that the biasing element is a spring. Toy vehicle track assembly according to claim 1, characterized in that it further comprises: a crank configured to wrap the body against the biasing member. A track-mounted toy vehicle impeller, characterized in that it comprises: a base portion; a pusher element rotationally coupled to the base portion, the pusher element being configured to move 360 degrees relative to the base portion, the pusher element including a plurality of coupling portions, each of the coupling portions being configured to engage a carrier vehicle. toy; and an alignment mechanism coupled to the pusher element, the alignment mechanism allowing the pusher element to rotate only a partial rotation repeatedly in response to the actuation of the pusher by the toy vehicle. Toy vehicle impeller according to claim 10, characterized in that the toy vehicle is a first toy vehicle and the pusher element is configured to engage and be actuated by sequential toy vehicles. Toy vehicle impeller according to claim 10, characterized in that the alignment mechanism includes at least one latch configured to selectively stop the rotation of the impeller element. Toy vehicle impeller according to claim 12, characterized in that the at least one lug includes three lugs arranged at equal intervals around the base. Toy vehicle impeller according to claim 10, characterized in that the partial rotation is one third of one rotation. A track-mounted toy vehicle impeller, characterized in that it comprises: a base portion; a pusher element rotationally coupled to the base portion, the pusher element being configured to move 360 degrees relative to the base portion, the pusher element including a plurality of engaging portions, a pusher coupled to the pusher element, the pusher element predisposing the pusher element to a rest position, and a tongue engaging with the pusher element to stop the pusher element during its rotation after actuation by a toy vehicle so that the pusher element rotates only a partial rotation. Toy vehicle impeller according to claim 15, characterized in that the resting position is a first resting position and the requesting element is configured to request the driving element to one of the first resting position; from the second resting position or the third resting position. Toy vehicle impeller according to claim 15, characterized in that one of the plurality of engaging portions engage a toy vehicle during partial rotation. Toy vehicle impeller according to claim 15, characterized in that it further comprises: a crank configured to transfer potential energy to the request element. Toy vehicle impeller according to claim 18, characterized in that each crank rotation transfers sufficient energy to the biasing element to allow three partial revolutions to the pusher element. Toy vehicle impeller according to claim 18, characterized in that the crank is rotated in a first direction and the impeller element rotates in a second opposite direction.