Abstract
This present application pertains to a toss game consisting of at least two angled boards with a geometrically shaped cut out for the tossed item to fall through. It also consists of a mechanism that will move the geometrically shaped cut out, or opening, in an oscillating geometric motion, thus increasing the skill required to play said toss game.
Claims
1. A Toss game assembly for one or more players comprising that complies with the American Cornhole Association regulation size assembly (top board 24 inches48 Inches, a circular hole 6 inches in diameter placed 12 inches from the side of the top board and 9 inches from the back of the top board, the back of board to be 12 inches off the surface it is placed upon, the front to be no less than 2 inches above the surface it is placed upon, and not more than 4 inches off the surface it is placed upon): A framework supporting an angled face board, the framework comprising two side frames, a front frame and a rear frame, the face board having a circular shaped opening of a size and shape allowing a tossed object to pass and fall through.
2. The toss game assembly of claim 1, wherein the tossed object comprises of a bean bag that is 6 inches square in shape or similar type of tossed object.
3. The assembly set forth in claim 1, which comprises of a Top Board, or entire assembly, which is able to move in a single oscillating geometric motion (swinging arc, vertical, horizontal or orbital) relative to the player.
4. The assembly set forth in claim 3 may be comprised of, but not limited to, a Top Board that is mounted to a Sub Board in a plurality of mechanical methods to create a plurality of single oscillating geometric motions.
5. The assembly set forth in claim 4 may be comprised of, but not limited to, a motor (electric, gas, air or spring) that drives the aforementioned plurality of mechanical methods throughout its desired single oscillating geometric motion that gives the circular opening its oscillating geometric motion for player (or players) to aim at.
6. The assembly set forth in claim 5, the motor, or other method of driving the aforementioned plurality of mechanical methods set forth in claim 5, is able to be either set to a constant velocity, or be changed in velocity to a different constant velocity or be set to be variable in velocity.
Description
BRIEF DESCRIPTION OF FIGURES
[0011] To further satisfy the recited claims, a detailed description of possible embodiments are provided with reference drawings included that do not limit the scope of the invention.
[0012] FIG. 1 is an exploded assembly depicting the Arc oscillating motion with item call-outs.
[0013] FIG. 1A is the bottom view of the Arc assembly with call-outs.
[0014] FIG. 1B is a detailed view of the linkage design that results in the Arc oscillating motion with call-outs.
[0015] FIG. 2 is an exploded assembly depicting the Horizontal oscillating motion with item call-outs.
[0016] FIG. 2A is the bottom view of the Horizontal assembly with call-outs.
[0017] FIG. 2B is a detailed view of the linkage design that results in the Horizontal oscillating motion with call-outs.
[0018] FIG. 3 is an exploded assembly depicting the Vertical oscillating motion with item call-outs.
[0019] FIG. 3A is the bottom view of the Vertical assembly with call-outs.
[0020] FIG. 3B is a detailed view of the linkage design that results in the Vertical oscillating motion with call-outs.
[0021] FIG. 4 is an exploded assembly depicting the Circular or orbital oscillating motion with item call-outs.
[0022] FIG. 4A is the bottom view of the Circular or orbital oscillating motion assembly with call-outs.
[0023] FIG. 4B is a detailed section view of the design that results in the Circular or orbital oscillating motion with call-outs.
[0024] FIG. 4C is a detailed enlarged view of the design that results in the Circular or orbital oscillating motion with call-outs.
DESCRIPTION OF THE INVENTION
[0025] The present invention shown here may be embodied in other specific forms without departing from its spirit or essential characteristics. The four embodiments herein are shown to address some of the different embodiments, but are not intended to limit the scope of the invention. Therefore the scope of the invention is indicated by the claims and their combination, in whole or in part, rather than the foregoing description.
[0026] The invention provides the means to make the geometrically shaped opening in the Top Board move in an oscillating geometric motion. FIG. 1 shows the exploded view of the embodiment which results in an oscillating Arc motion. In FIG. 1A, Item 7, Flywheel, is attached to the output shaft of Item 4, Motor, to induce a rotary motion of Flywheel. Item 4, Motor, is mounted and fixed to Item 2, Sub Board. The Flywheel is joined to Item 8, Link, which allows relational circular motion between Flywheel and Link, and drives the Link smoothly in a circular motion. The opposite end of the Link is connected to the protruding pin in Item 3, Top Board, which allows relational circular motion and drives the Top Board. The Top Board has a protruding pin at the base of the Top Board, which aligns with Item 5, Bearing-Flanged, 1 ID, which allows free rotational motion. All these elements together create an Oscillating Arc motion of the geometric cut-out in the Top Board to allow the bag to fall through. Also, the Top Board has a plurality of Item 10, Bar-Slide, Short, which are made from a low friction material to allow smooth motion. Item 2, Sub-Board, has large cut-out in it to allow a bag to fall through easily throughout the oscillation motion of Top Board.
[0027] FIG. 2 shows the exploded view of the embodiment which results in an oscillating Horizontal motion. In FIG. 2B, Item 6, Flywheel, is attached to the output shaft of Item 3, Motor, to induce a rotary motion of Flywheel. Item 3, Motor is mounted and fixed to Item 2, Sub Board. The Flywheel is joined to Item 7, Link, which allows relational circular motion between Flywheel and Link, and drives the Link smoothly in a circular motion. The opposite end of the Link is connected to the protruding pin in Item 4, Top Board, which allows relational circular motion and drives the Top Board. The Top Board has two protruding pins that align with two horizontally aligned slots in Item 2, Sub Board. These pins are aligned with the slots, which allows the pins to slide freely in the slots which results in an oscillating Horizontal motion of the geometrically shaped opening in Item 4, Top Board.
[0028] All these elements together create an Oscillating Horizontal motion of the geometric cut-out in the Top Board to allow the bag to fall through. Also, the Top Board has a plurality of Item 10, Bar-Slide, Short, which are made from a low friction material to allow smooth motion. Item 2, Sub-Board, has large cut-out in it to allow a bag to fall through easily throughout the Horizontal oscillation motion of Top Board.
[0029] FIG. 3 shows the exploded view of the embodiment which results in an oscillating Vertical motion. In FIG. 3B, Item 6, Flywheel, is attached to the output shaft of Item 3, Motor, to induce a rotary motion of Flywheel. Item 3, Motor, is mounted and fixed to Item 2, Sub Board. The Flywheel is joined to Item 7, Link, which allows relational circular motion between Flywheel and Link, and drives the Link smoothly in a circular motion. The opposite end of the Link is connected to a protruding pin in Item 4, Top Board, which allows relational circular motion and drives the Top Board. The Top Board has two protruding pins that align with two vertically aligned slots in Item 2, Sub Board. These pins are aligned with the slots, which allows the pins to slide freely in the slots which results in an oscillating Vertical motion of the geometrically shaped opening in Item 4, Top Board. All these elements together create an Oscillating Vertical motion of the geometric cut-out in the Top Board to allow the bag to fall through. Also, the Item 2, Sub Board has a plurality of Item 9, Bar-Slide, Vertical Version and Item 10, Bar-Slide, Short, attached to it, which are made from a low friction material to allow smooth motion of Item 4, Top Board. Item 2, Sub-Board, has large cut-out in it to allow a bag to fall through easily throughout the Vertical oscillation motion of Top Board.
[0030] It is also possible in these embodiments of the oscillating Horizontal and Vertical motions, to have a circular insert which has the slot feature in the insert which would allow the slot to be aligned in an angular position to generate an oscillating angular motion other than Horizontal or Vertical. That embodiment is not illustrated in this document, but is consistent with the spirit or essential characteristics of the invention described and depicted in this document.
[0031] FIG. 4 shows the exploded view of the embodiment which results in an oscillating Circular or Orbital motion. FIG. 4B shows the cross sectional view of the assembly. Item 4, Motor, is coupled to Item 10, Connecting Shaft Adapter, coaxially to output shaft of Motor and fixed, that enables rotational transmission of movement from Motor output shaft to Connecting Shaft Adapter. Item 6, Flywheel, and Item 8, Pulley, are coupled coaxially and fixed to Item 10, Connecting Shaft Adapter, which transmits rotational movement from Item 4, Motor's output shaft. FIG. 4A shows the bottom view of the assembly. Item 4, Motor, is mounted and fixed to Item 2, Sub Board. Item 6, Flywheel is connected to the protruding pin on Item 3, Top Board, which allows relational circular motion between Flywheel and Top Board, and transmits rotational motion to Top Board. Also, Item 9, Timing Belt, is attached to Item 8, Pulley, which has rotational motion transmitted via Item 10, Connecting Shaft Adapter. Item 8, Pulley transmits motion to Item 9, Timing Belt, which is connected to another Item 8, Pulley, aligned linearly at some linear distance from Item 4, Motor. In this distal location of Item 8, Pulley, it is coupled with Item 10, Connecting Shaft Adapter, coaxially and fixed. Pulley transmits rotational motion to Connecting Shaft Adapter. Item 6, Flywheel is coupled to Item 10, Connecting Shaft Adapter, coaxially and fixed, so they rotate in unison. FIG. 4C Item 6, Flywheel, is connected to the protruding pin on Item 3, Top Board, which allows relational circular motion between Flywheel and Top Board, and transmits rotational motion to Top Board. Item 10, Connecting Shaft Adapter, passes through coaxially, in both instances, Item 11, Bearing, and is pressed and fixed into Item 2, Sub Board. Item 6, Flywheel is connected to the protruding pin on Item 3, Top Board, which allows relational circular motion between Flywheel and Top Board, and transmits rotational motion to Top Board. All these elements together create a synchronous rotation of both Flywheels, through the transmission of motion through Item 9, Timing Belt, to Item 8, Pulley, and both Pulleys are synchronized in their radial alignment throughout their rotation cycles. This allows for Item 6 in both locations to have synchronized radial alignment throughout their rotation cycles. Now the geometric opening in Item 3, Top Board, will move in a continuous, Circular Oscillating motion. Also, the Item 2, Sub Board, has a plurality of Item 12, Bar-Slide, Vertical Version and Item 13, Bar-Slide, Short, attached to it, which are made from a low friction material to allow smooth motion of Item 3, Top Board. Item 2, Sub-Board, has large cut-out in it to allow a bag to fall through easily throughout the Circular oscillation motion of Top Board.
[0032] The present invention shown here may be embodied in other specific forms without departing from its spirit or essential characteristics. The four embodiments herein are shown to address some of the different embodiments, but are not intended to limit the scope of the invention and are for illustrative purposes only.
