A modular starting gate having a truss module, a door releasing module, a stall divider module, a front door module, a rear door module, a towing module, and a wheel assembly module. The door releasing module includes a roll-bar having articulated members that are coupled to the front door module via a coupling bar and a turnbuckle adjuster. The roll-bar is coupled to the truss module via a bearing and includes a first section coupled to a second section via a u-joint. A rebound stop is coupled to the starting gate, wherein the rebound stop has a first portion mounted to the front door module which cooperates with a second portion coupled to the stall divider module.
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0. 13. A starting gate, comprising:
a horse stall having first and second sides;
a door coupled to the first side of the horse stall; and
means for actuating the door, wherein said means for actuating includes a roll-bar coupled to the horse stall via a plurality of bearings, said roll-bar comprising:
a first section coupled to a second section by a u-joint, wherein said roll-bar spans at most two bearings without a u-joint;
means for rotating the roll-bar coupled to the horse stall;
an articulated member extending from the roll-bar; and
coupling bar coupled to the articulated member.
0. 28. A starting gate, comprising:
a horse stall having first and second sides;
a door coupled to the first side of the horse stall;
a door latch; and
means for actuating the door, wherein said means for actuating includes a roll-bar coupled to the horse stall via a plurality of bearings, said roll-bar comprising:
a first shaft section coupled to a second shaft section by a u-joint, wherein said first shaft section spans no more than two bearings without a u-joint;
means for rotating the roll-bar coupled to the horse stall;
an arm extending from the roll-bar; and
a coupling bar coupled between said arm and said door latch for actuating said door latch.
0. 21. A horse race starting gate, comprising:
a plurality of stall divider modules, plural of said plurality of stall divider modules comprising at least a front support column, a back support column and a plurality of lengthwise braces welded together as a unit prior to welding said stall divider module to a truss module;
a truss module having a plurality of said stall divider modules welded thereto;
a door release module coupled to the truss module;
a front door coupled to the stall divider module; and
a rebound stop having a first portion coupled to the front door and a second portion coupled to the stall divider module, the first portion having a first member for frictionally engaging the second portion.
0. 1. A horse race starting gate, comprising:
a truss module, the truss module positioned in a first orientation;
a door release module coupled to the truss module;
a stall divider module coupled to the truss module;
a front door coupled to the stall divider module; and
a rebound stop having a first portion coupled to the front door and a second portion coupled to the stall divider module, the first portion having a first member for frictionally engaging the second portion.
0. 2. The horse race starting gate of
0. 3. The horse race starting gate of
0. 4. The horse race starting gate of
0. 5. The horse race starting gate of
0. 6. The horse race starting gate of
0. 7. The horse race starting gate of
0. 8. The horse race starting gate of
0. 9. The horse race starting gate of
0. 10. The horse race starting gate of
0. 11. The horse race starting gate of
0. 12. The horse race starting gate of
0. 14. The starting gate of
0. 15. The starting gate of
0. 16. The starting gate of
0. 17. The starting gate of
0. 18. The starting gate of
0. 19. A starting gate, comprising:
an overhead support structure;
first and second stall dividers coupled to the overhead support structure, the first and second stall dividers having first and second ends, wherein the first ends of the first and second stall dividers are adjacent each other and the second ends of the first and second stall dividers are adjacent each other;
a first set of doors coupled to the first ends of the first and second stall divider;
a second set of doors coupled to the second ends of the first and second stall dividers;
a door release mechanism coupled to the overhead support structure, the door release mechanism comprising:
a roll-bar having a first section coupled to a second section by a u-joint, wherein said roll-bar spans at most two bearings without a u-joint;
means for rotating the roll-bar coupled to the horse stall;
a plurality of articulated members extending from the roll-bar; and
a coupling bar coupled to each of the plurality of articulated members wherein
a first coupling bar is coupled to a first door of the first set of doors and a second coupling bar is coupled to a second door of the first set of doors; and
first and second rebound stops coupled to the first and second doors, respectively.
0. 20. The starting gate of
0. 22. The horse race starting gate of
0. 23. The horse race starting gate of
0. 24. The horse race starting gate of
0. 25. The horse race starting gate of
0. 26. The horse race starting gate of
the means for rotating the roll-bar comprises one of a solenoid and a magnet.
0. 27. The horse race starting gate of
the first portion of the rebound stop is vertically adjustable by means of vertical slots operatively disposed between said first portion and said front door.
0. 29. The starting gate of
0. 30. The starting gate of
0. 31. The starting gate of
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This invention relates, in general, to starting gates and, more particularly, to starting gates used for horse races.
Horse races are typically run on an oval shaped track having a start line and a finish line. Prior to starting the race, a starting gate is positioned at the start line and the horses are placed in the stalls of the starting gate. The race is started by simultaneously opening the front doors of each individual stall, thereby releasing the horses so they can race around the track. The starting gate is moved away from the track immediately after the race has begun to prevent it from impeding the horses as they run around the track. Chamberlain teaches in U.S. Pat. No. 4,311,116 an in-motion starting gate having individual doors that are opened using hydraulic cylinders coupled to the individual doors. Georgette et al. teach in U.S. Pat. No. 2,808,026 opening the doors by using an electromagnet mounted to each individual door. The starting gates in these patents use many parts or components to open the individual doors. As those skilled in the art are aware, the greater the number of components, the greater the likelihood of at least one of the components failing. A common occurrence with some starting gates is gate failure where one of the front doors either fails, allowing a horse to “leak out” of the starting gate, or does not open, holding one horse in the stall. Along similar lines, one door may open more slowly than the others, either putting the horse and rider in that gate at a disadvantage or more often causing the race to be nullified. Because of the large sums of money wagered on individual races, unreliable starting gates negatively impact the profits of both the race track operators, the starting gate owners, and the horse owners.
Accordingly, what is needed is a safe, low cost, reliable starting gate.
The present invention satisfies the foregoing need by providing a cost efficient, reliable starting gate. In one aspect of the present invention, the starting gate comprises subassemblies that are manufactured to predetermined dimensions with controlled tolerances, wherein the subassemblies are interchangeable. In one embodiment the subassemblies include a truss module, a door release module coupled to the truss module, a stall divider module coupled to the truss module, a front door coupled to the stall divider module, and a rebound stop having a first portion coupled to the front door and a second portion coupled to the stall divider module, the first portion having first member for frictionally engaging the second portion. In another aspect, the staring gate comprises a horse stall having a first set of doors coupled to one end of the horse stall and a second set of doors coupled to the opposite end of the horse stall. A mechanism for opening the first set of stalls is coupled to the horse stall wherein the mechanism includes a roll-bar coupled to the horse stall via a plurality of bearings. The roll-bar has a first section coupled to a second section by a U-joint, wherein said roll-bar spans at most two bearings without a U-joint, a means for rotating the roll-bar coupled to the horse stall, an articulated member extending from the roll-bar; and a coupling bar coupled to the articulated member.
The present invention will be better understood from a reading of the following detailed description, taken in conjunction with the accompanying drawing figures in which like references designate like elements and in which:
Properly operating starting gates are critical to the success of each horse race. In accordance with the present invention, a starting gate is provided that is modular, reliable, safe, and cost efficient. Because the starting gate is modular, it offers savings in both its cost of manufacture and the time needed for its manufacture. Further, the modularity increases the tolerance control which results in an improvement in reliability of the starting gate and permits interchangeability of parts.
Referring now to
The first end of interior vertical brace 121 is welded to lower rail 111 such that it is proximal to, but spaced apart from, the first end of lower rail 111. The second end of interior vertical brace 121 is welded to the first end of upper rail 112. The first end of interior vertical brace 129 is welded to lower rail 111 such that it is proximal to, but spaced apart from, the second end of lower rail 111. The second end of interior vertical brace 129 is welded to the second end of upper rail 112. Brace 125 is welded to the centers of rails 111 and 112. Interior vertical braces 122, 123, and 124 are welded to the portions of rails 111 and 112 between vertical braces 121 and 125, and interior vertical brace 126, 127, and 128 are welded to the portions of rails 111 and 112 between vertical braces 125 and 129.
End braces 117 and 118 are welded to the first and second ends, respectively, of lower rail 111 and are substantially parallel to each other. In accordance with this embodiment, end braces 117 and 118 are shorter than interior vertical braces 121-129. One end of angled rail 113 is welded to the end of upper rail 112 that is adjacent to brace 121 and the other end of angled rail 113 is welded to end brace 117. One end of angled rail 114 is welded to the end of upper rail 112 that is adjacent to brace 129 and the other end of angled rail 114 is welded to end brace 118. It should be understood that end braces 117 and 118 are optional features. Thus, in an alternative embodiment, one end of angled rail 113 is welded to the end of upper rail 112 that is adjacent to brace 121 and the other end of angled rail 113 is welded to lower rail 111. Likewise, one end of angled rail 114 is welded to the end of upper rail 112 that is adjacent to brace 129 and the other end of angled rail 114 is welded to lower rail 111. Alternatively, rails 111 and 112 can be the same length, wherein angled rails 113 and 114 are not used and end braces 118 are welded to the ends of rails 111 and 112.
Interior diagonal braces 131-138 are welded between rails 111 and 112. In particular, the first end of interior diagonal brace 131 is welded to the portion of lower rail 111 adjacent interior vertical brace 121 and the first end of interior diagonal brace 132 is welded to the portion of lower rail 111 adjacent a first side of interior vertical brace 123. The second ends of interior diagonal braces 131 and 132 are welded to the portions of upper rail 112 adjacent interior vertical brace 122, wherein the second ends are welded on opposite sides of interior vertical brace 122. Thus, diagonal braces 131 and 132, rail 111, and interior vertical brace 122 form a triangular shaped structure comprising two right triangles sharing a common side.
The first end of interior diagonal brace 133 is welded to the portion of lower rail 111 adjacent a second side of interior vertical brace 123 and the first end of interior diagonal brace 134 is welded to the portion of lower rail 111 adjacent a first side of interior vertical brace 125. The second ends of interior diagonal braces 133 and 134 are welded to the portions of upper rail 112 adjacent interior vertical brace 124, wherein the second ends are welded on opposite sides of interior vertical brace 124. Diagonal braces 133 and 134, rails 111, and interior vertical brace 124 form a triangular shaped structure comprising two right triangles sharing a common side.
The first end of interior diagonal brace 135 is welded to the portion of lower rail 111 adjacent a second side of interior vertical brace 125 and the first end of interior diagonal brace 136 is welded to the portion of lower rail 111 adjacent a first side of interior vertical brace 127. The second ends of interior diagonal braces 135 and 136 are welded to the portions of upper rail 112 adjacent interior vertical brace 126, wherein the second ends are welded on opposite sides of interior vertical brace 126. Diagonal braces 135 and 136, rail 111, and interior vertical brace 126 form a triangular shaped structure comprising two right triangles sharing a common side.
The first end of interior diagonal brace 137 is welded to the portion of lower rail 111 adjacent a second side of interior vertical brace 127 and the first end of interior diagonal brace 138 is welded to the portion of lower rail 111 adjacent to first side of vertical brace 129. The second ends of interior diagonal braces 137 and 138 are welded to the portions of upper rail 112 adjacent interior vertical brace 128, wherein the second ends are welded on opposite sides of interior vertical brace 128. Diagonal braces 137 and 138, rail 111, and interior vertical brace 128 form a triangular shaped structure comprising two right triangles sharing a common side.
Trusses 110 and 140 are coupled together using horizontal coupling braces and X-shaped cross-braces to form truss module 100. Horizontal coupling braces 171 are welded between lower rails 111 of trusses 110 and 140 and a plurality of horizontal coupling braces 172 are welded between upper rails 112 of trusses 110 and 140. More particularly, truss 110 is aligned in a spaced apart parallel relationship with truss 140 and one end of each horizontal coupling brace 171 is welded to lower rail 111 of truss 110 and each other end is welded to lower rail 111 of truss 140. Preferably, a horizontal coupling brace 171 is associated with each set of interior vertical braces 121-129, where a horizontal coupling brace 171 is welded to lower rails 111 at each location adjacent a corresponding interior vertical brace 121-129. Thus, a horizontal coupling brace 171 is welded between horizontal rail 111 of truss 110 and horizontal rail 111 of truss 140 at locations adjacent interior vertical braces 121, a horizontal coupling brace 171 is welded between horizontal rail 111 of truss 110 and horizontal rail 111 of truss 140 at locations adjacent interior vertical braces 122, a horizontal coupling brace 171 is welded between horizontal rail 111 of truss 110 and horizontal rail 111 of truss 140 at locations adjacent interior vertical braces 123, etc.
Likewise, a separate horizontal coupling brace 172 is welded between upper rails 112 adjacent each location having an interior vertical brace 121-129. Thus, a horizontal coupling brace 172 is welded between upper rail 112 of truss 110 and upper rail 112 of truss 140 at locations adjacent interior vertical braces 121, a horizontal coupling brace 172 is welded between upper rail 112 of truss 110 and upper rail 112 of truss 140 at locations adjacent interior vertical braces 122, a horizontal coupling brace 172 is welded between upper rail 112 of truss 110 and upper rail 112 of truss 140 at locations adjacent interior vertical braces 123, etc. Horizontal coupling braces 171 and 172 are substantially parallel to each other and substantially perpendicular to trusses 110 and 140.
Trusses 110 and 140 are further coupled to each other by a plurality of X-shaped cross-braces 180. Each X-shaped cross-brace has four legs 181, 182, 183, and 184, wherein legs 181 and 182 are welded to lower rail 11 and upper rail 112, respectively, of truss 110, and legs 183 and 184 are welded to lower rail 111 and upper rail 112, respectively, of truss 140. Preferably, an X-shaped cross-brace 180 is positioned to be between interior vertical braces 121 of trusses 110 and 140, an X-shaped cross-brace 180 is positioned to be between interior vertical braces 122 of trusses 110 and 140, an X-shaped cross-brace 180 is positioned to be between interior vertical braces 123 of trusses 110 and 140, etc. Thus, legs 181 and 182 of one X-shaped cross-brace are welded to portions of rails 111 and 112, respectively, that are adjacent interior vertical brace 121 of truss 110, and legs 183 and 184 are welded to portions of rails 111 and 112, respectively, that are adjacent interior vertical brace 121 of truss 140. Likewise, legs 181 and 182 of another X-shaped cross-brace 180 are welded to portions of rials 111 and 112, respectively, that are adjacent interior vertical brace 122 of truss 110, and legs 183 and 184 are welded to a portion of rails 111 and 112, respectively, that are adjacent interior vertical brace 122 of truss 140. Preferably, there is an X-shaped cross-brace between each corresponding interior vertical brace 121-129 of trusses 110 and 140 and, thus, between corresponding coupling braces 171 and 172.
In accordance with the present invention, the dimensions of truss module 100 are maintained within very tight tolerances, e.g., the lengths and widths of trusses 110 and 140 and their individual components as well as braces 171 and 172 and X-shaped braces 180 are maintained within very tight tolerances.
Although not shown in
It should be noted that when stall door release module 200, stall divider module 300, front door module 500, and rear door module 600 are mounted to truss module 100, trusses 110 and 140 may sag. Thus, it may be desirable to manufacture trusses 110 and 140 with a camber or bow to compensate for the sag so that trusses 110 and 140 become straight when starting gate 10 is complete.
Now referring to
In accordance with the present invention, the dimensions of stall divider module 300 are maintained within very tight tolerances, i.e., the lengths and widths of platform 301, front support column 302, back support column 303, caboose 335, front fender 307, rear fender 308, hinges 330 and 331, the plurality of lengthwise braces 313, and the locations of hinges 330 and 331 are maintained within tight tolerances.
Briefly referring to
A quadrilateral frame 560 having a top side 561, a bottom side 562, a mounting side 563, and a latching side 564 is welded between vertical supports 550 and 551 in the region between horizontal brace 554 and horizontal rail 553. Frame 560 is welded or tacked in position such that top side 561 abuts horizontal brace 554, bottom side 562 abuts horizontal rail 553, mounting side 563 abuts vertical support 550, and latching side 564 abuts vertical support 551. Further, a pair of spaced apart horizontally oriented braces 566 and 567 are welded between mounting and latching sides 563 and 564, respectively.
A first end of a vertical rail 571 is welded to a first end of a horizontal rail 572 and the second end of vertical rail 571 is welded to a first end of a horizontal rail 573. The second end of horizontal rail 572 is welded to a third mid-portion of vertical rail 551 and the second end of horizontal rail 573 is welded to the second end of vertical rail 551. Vertical rail 571 is positioned to be substantially parallel to vertical rails 550 and 551 and substantially perpendicular to horizontal rails 572 and 573. A vertical brace 575 is welded between horizontal rails 553 and 572 and is spaced apart from but proximal to vertical rail 551. It should be noted that horizontal rails 553 and 572 and vertical brace 575 cooperate to form a C-shaped or “sideways” U-shaped structure which allows door 502 to rotate over front fender 307 without touching it.
A quadrilateral frame 580 having a top side 581, a bottom side 582, a mounting side 583, and a latching side 584 is welded between vertical rails 551 and 571 in the region between horizontal rail 572 and horizontal rail 573. Frame 580 is welded or tacked in position such that top side 581 abuts horizontal rail 572, bottom side 582 is spaced apart from horizontal rail 573, mounting side 583 abuts vertical support 571, and latching side 584 abuts vertical support 551. Further, a horizontally oriented brace 585 is welded between mounting and latching sides 583 and 584, respectively.
A pivot bar or latch arm 531 is pivotally mounted to horizontal brace 557 and a pivot bar or latch arm 532 is pivotally mounted to horizontal brace 567. Pivot bars 531 and 532 have a hooked end and a coupling end. The hooked ends each pivot bar have a hook that is designed to mate with latches on door 503. The coupling end of pivot bar 531 has two holes wherein one hole is for coupling with a gating arm, e.g., one of gating arms 211 shown in
Front door 503 is similar in construction to front door 502 and is therefore comprised of vertical rails 550, 551, 571, and 572; horizontal rails 552, 553, 554, and 573; horizontal braces 554, 556, and 557; vertical braces 558 and 575; quadrilateral frames 560 and 580; rebound stops 538 (described hereinafter); and torsion springs 546 and 547. It should be noted that horizontal rails 553 and 572 and vertical brace 575 cooperate to form a C-shaped or “sideways” U-shaped structure which allows door 503 to rotate over fender 307 without touching it.
It should be understood that pivot bars are not mounted to front door 503. Rather, latches 533 and 534 are mounted to vertical rail 551 of front door 503 wherein latches 533 and 534 are designed to cooperate with the respective hooks on pivot arms 531 and 532 to hold doors 502 and 503 closed. It should be further understood that to simplify the description, only a single set of front doors is described; however, the description applies to each set of front doors of starting gate 10. Although front doors 502 and 503 have been described as having two sets of pivot bars and hooks, this is not a limitation of the present invention. For example, there can be one pivot bar and hook or more than two sets of pivot bars and hooks. Pivot bars and hooks are also referred to as gating arms and latches, respectively.
Similar to truss module 100 and stall divider module 300, the dimensions of each component of front door module 500 are held to within very tight tolerances.
Still referring to
Rebound stops 538 for front doors 502 and 503 are mounted to the front doors and to the front fenders. Briefly referring to
Referring to
Back door structure 600 includes a door latching mechanism 670 that comprises a lever 671 coupled to a locking plate 672 via a coupling bar 673. Although coupling bar 673 is shown as a piece of metal, this is not a limitation of the present invention. For example, coupling bar 673 can be comprised of several lengths of chain to apply an up-pressure. Lever 671 has a handle end, a coupling end, and a centrally located fastening portion. The fastening portion is for pivotally fastening lever 671 to diagonal brace 656 and the coupling end is for pivotally coupling the coupling end to a first end of coupling bar 673. The handle end is for latching and unlatching the door, i.e., moving the handle in the upward direction latches the door and moving the handle in the downward direction unlatches the door. Locking plate 672 is a rectangularly shaped plate having one side pivotally mounted to diagonal brace 658 and an opposite side pivotally mounted to the second end of coupling bar 673. Locking plate 672 cooperates with a plate locking mechanism 676 to latch doors 602 and 603. Briefly referring to
Similar to truss module 100, stall divider module 300, and front door module 500, the dimensions of each component of back door module 600 are held to within very tight tolerances. It should be appreciated that front and back door modules serve as gating means for starting gate 10.
Referring to
Roll-bar 210 is comprised of two pipes 225 and 226 connected by a U-joint 227. Preferably, pipes 225 and 226 are cylindrically shaped. Roll-bar 210 is coupled to interior vertical braces 121-129 via bearings 221 mounted to bearing mounting plates 217. Preferably, roll-bar 210 is designed such that is does not span more than two bearings without a U-joint and it does not span more than two stalls without a bearing. An advantage of building roll-bar 210 in sections connected by U-joints and mounting them to truss 110 using bearings located at predetermined locations is that it provides flexibility to the roll-bar when truss module 100 bends under the weight of the stalls. In other words, as trusses 110 and 140 bend, the U-joints cooperate with the bearings to provide flexibility to the roll-bar thereby preventing it from binding as occurs in prior art gates. Roll-bar 210 also include gating arms 211 extending therefrom.
Referring now to
Door release module 200 also has a rotation stop 260 having a coupling end 261 and a contact pad 262. Contact pad 262 contacts stopping or rotation stop pad 263 when magnet 230 has been de-energized to prevent roll-bar 210 from over-rotating and becoming damaged. Optionally, rotational stop 260 is coupled to roll-bar 210 via a swivel plate 270. In accordance with the first embodiment, door release module 200 comprises a magnet 230 and rotation stop 260. Alternatively, door latch actuator 230 comprises a solenoid (not shown).
Further, door release module 200 includes a spring mechanism 280 having a spring 281 coupled to a clamp 282 via a cable 282. Clamp 282 is mounted to diagonal cross brace 142. Spring mechanism 280 pulls arm 211 up when magnet 230 is de-energized thereby opening the individual doors. To cock roll-bar 210, a pipe is inserted into swivel plate 270 and roll-bar 210 is rotated until magnet 230 holds (or until the latch engages when a solenoid is used instead of a magnet). It should be understood that there can be a spring mechanism associated with each gating arm 211; however, the number of spring mechanisms is determined by the difficulty of roll-bar 210 opening front doors 502 and 503, i.e., each gating arm has a provision for a spring mechanism but each gating arm may not have a spring mechanism.
Gating arm 211 is coupled to coupling bar 586 by means of a chain 212. Alternatively, a cable or similar flexible fastener could be used to couple gating arm 211 to coupling bar 586. An advantage of using chain 212 is that it provides flexibility when gating arm 211 is moved. It should be noted that coupling bar 586 is shown and described with reference to FIG. 4.
Referring now to
Similar to truss module 100, stall divider module 300, front door module 500, and back door module 600, the dimensions of each component of door release module 200 are held to within very tight tolerances.
Referring again to FIG. 1 and in accordance with an embodiment of the present invention, towing module 700 comprises an axle assembly 710 having a set of wheels 712 mounted thereto. Axle assembly 710 is welded to a towing platform 714. One end of a support column 716 is welded to an end of truss 110 and an opposing end of support column 716 is welded to towing platform 714. One end of another support column 716 is welded to an end of truss 140 and an opposing end of support column 716 is welded to towing platform 714. A set of braces 718 are welded between support columns 716 and towing platform 714.
Referring to
Referring again to
Similar to truss module 100, door release module 200, stall divider module 300, front door module 500, and back door module 600, the dimensions of each component of transport modules 700 and 800 are held to within very tight tolerances.
Padding is added to starting gate 10. Padding is particularly important to have on the insides of the stall including the inside of the front door, the inside of the rear door, the walls of the stall, the support columns and the bottom surfaces of the trusses. Padding helps to protect the horse, the jockey, and any ground men from injury should an accident occur.
By now it should be appreciated that a starting gate has been provided. In accordance with the present invention, the starting ate comprises a door release module, a stall divider module, a front gate module, a rear gate module, a towing module, and a wheel module coupled to a truss module. Each module is manufactured to be within very tight specifications and these specifications can be maintained when the modules are assembled into the final starting gate structure. The components of the staring gates can be painted after they've been assembled as modules rather than after the starting gate has been manufactured. The paint can be further protected by using plastic washers and plastic tape in areas where friction may cause the paint to wear, e.g., in the pivot arm region. The present invention also enables interchangeability between the towing module and the wheel module as well as interchangeability between different starting gates. This feature gives horse track owners flexibility in the direction they can move the starting gate from the track. Further, the present invention allows towing the starting gate at highway speeds. Another aspect of interchangeability is that the front and back doors are removable and can be easily replaced in the event that one becomes damaged without damaging the starting gate. For example, back doors of the present invention can be quickly replaced by another back door by removing the damaged door and replacing it with an undamaged door (unlike previous starting gates which required cutting the starting gate to remove the back door). Because of the tight tolerances and the uniformity of each starting gate, they have a distinctive look that provides an advertising advantage.
Although certain preferred embodiments and methods have been disclosed herein, it will be apparent from this foregoing disclosure to those skilled in the art that variations and modifications of such embodiments and methods may be made without departing from the spirit and scope of the invention.
Kammerzell, Donald L., Manion, Scott A., O'Connor, Mike T.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
2232675, | |||
2273493, | |||
2808026, | |||
2868168, | |||
2955570, | |||
3604399, | |||
3703883, | |||
4070988, | Sep 01 1976 | Starting apparatus for rodeo events | |
4102307, | Sep 13 1976 | WIGGINS, KEITH E , JR | Portable livestock stall |
4130087, | Jun 07 1977 | Starting bar attachment for starting gates | |
4311116, | Jul 28 1980 | In-motion starting gate | |
4498666, | Mar 24 1981 | Racetracks | |
6637094, | Aug 13 2001 | K-ZELL METALS, INC | Method for manufacturing a horse race starting gate |
674162, | |||
20010013319, |
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