Ferris wheel and similar rides are well known in the art. In the standard Ferris wheel, the rider carriages are mounted on a vertical wheel and the wheel itself is rotated. Several prior art designs of stationary wheel type rides are known, or roller coaster type rides with a carriage that goes around the stationary track. These rides present a number of difficulties, including complexity and rider evacuation issues in the event of an emergency.
The foregoing example of the related art and limitations related therewith are intended to be illustrative and not exclusive. Other limitations of the related art will become apparent to those of skill in the art upon a reading of the specification and a study of the drawings.
One aspect of the disclosure is to provide a vertical wheel type ride that can be in a shape other than a circle. Tracks could be designed in any number of geometric shapes, including ovals, triangles and asymmetric designs.
One aspect is to provide a support carriage that is driven along the stationary track via one continuous loop linkage with a rider carriage rotationally attached to the support carriage such that the rider carriage can rotate freely around a suspension bar of the support carriage.
One aspect of the present disclosure is to provide a repair and evacuation means such that any rider carriage can be reached quickly.
The following embodiments and aspects thereof are described and illustrated in conjunction with systems, tool and methods which are meant to be exemplary and illustrative, not limiting in scope. In various embodiments, one or more of the above described problems have been reduced or eliminated, while other embodiments are directed to other improvements.
A stationary track wheel ride is disclosed where a chain of rider carriages (gondolas) are driven around the stationary track. The rider carriages are rotationally mounted on axles on a support frame that allow the rider carriages to rotate around the axles so that the floor of the rider carriage remains approximately level with the ground while the rider carriage travels around the stationary track. One embodiment has an active sway control mechanism to control the amount of sway in the rider carriage. Possible embodiment of drive mechanisms include: a drive cable mechanism, motors attached to the track to drive the rider carriage train using drive wheels contacting some portion of the rider carriage. Motors attached to the rider carriage with drive wheels contacting the track. The track can be formed using a tri-cord truss system and/or a plate and girder system. Other possible structures could be used to form the stationary track as well.
One embodiment of an emergency access assembly is mounted on a separate track that is mounted next the track that supports the rider carriages. The emergency access assembly has a frame that moves on the separate track with an emergency access carriage is rotationally mounted on an axle mounted on the frame. The emergency access carriage is mounted on its axle such that the floor of the emergency access carriage is approximately co-planar with the floor of the rider carriage when the emergency access carriage is alongside the rider carriage.
One embodiment of the emergency access assembly is mounted on a separate track from the rider carriage and in one embodiment the emergency access assembly is mounted on the same track as the rider carriage.
In addition to the exemplary aspects and embodiments described above, further aspects and embodiments will become apparent by reference to the accompanying drawings forming a part of this specification wherein like reference characters designate corresponding parts in the several views.
a is a front plane view of the second embodiment of the track.
a-22d are views of the drive wheel assembly.
a-b are views of the emergency carriage drive wheels assembly.
Before explaining the disclosed embodiment of the present invention in detail, it is to be understood that the invention is not limited in its application to the details of the particular arrangement shown, since the invention is capable of other embodiments. Exemplary embodiments are illustrated in referenced figures of the drawings. It is intended that the embodiments and figures disclosed herein are to be considered illustrative rather than limiting. Also, the terminology used herein is for the purpose of description and not of limitation.
Referring first to
A passenger loading area (not shown) could be located at one area at the bottom of the ride or raised to be on one side. Any number of known in the art ways of designing a passenger loading area could be utilized. For example legs 107 and 108 could be on opposing sides of some sort of viewing area of interest, for example an aquarium or natural cave and the passenger loading area could be located on one side and not at the bottom of the ride 100 to provide the riders with a view at the bottom of the ride 100.
Referring next to
The support carriages 111 have rigid frame 114 with base 115 to which the roller mounts 204 are attached. The base 115 is shown as an open frame in
As seen in
In case there is a need to access a rider carriage 110 that is not located at the loading area and cannot be moved to the loading area for some reason (mechanical failure etc.) an emergency access assembly 300 is provided, as seen in
The base 304 is mounted on to rail 301 and 302 with roller mounts 204 as described above. The base 304 extends above the support rails 101 and 102. The base 304 also spaces the carriage support 305 far enough from the side frame 116 to allow the emergency carriage 308 to be move alongside the support carriage 111 without coming into contact with the support carriage 111 or the tri-mode truss rails 101, 102 and 103. The spacing is enough to allow the emergency access assembly 300 to move freely around the support track S, but is close enough that gangplank 310 can be used to connect the rider carriage 110 to the emergency carriage 308.
The emergency access carriage 308 is mounted on axle 311 on gimbaled bearings 118. The axle 311 extends from the top of carriage support 305 as can be seen in
The flat link 403 is pivotally connected at opposing ends 412 to a second flat link 404 which also has a substantially flat surface 408. In the depicted embodiment second flat link 404 pivotally connects at the opposing ends 409 to the flat link 403 on the next carriage.
The flat links 403 and 404 form two continuous chains around the perimeter of the ride 100, providing the linkage the three rods 120 provided in the other embodiment. Since the flat links provide two connections on each side of the carriage, it is possible to reduce the number of rods 102 used to link the support carriages 111. In the embodiment depicted in
In both the embodiments of
The track 1001 is supported and stiffened with connecting cables 1003 and stay cables 1004. The connecting cables 1003 connect to the track 1001 and the hub 1005. The stay cables 1004 attach to ground anchors 1006, of which there are four in the depicted embodiment. As shown in
The hub 1005 is an epoxy coated steel structure that is about 10 feet (3 meters) in diameter and about 10 feet (3 meters) long in the depicted embodiment. A sign can be attached to each end of the hub 1005. The hub 1005 has a hatch (not shown) to access to the interior for cable tensioning purposes. The interior of the hub can house lighting control panels. The hub can have a hoist or davit crane system (not shown) to lift tools and materials to the hatch. Ladder access from the bottom of the rim to the hub hatch can be provided via a ladder mounted between one set of spoke cables (not shown).
On each side of the track 1001, there are also stay cables 1004 that provide lateral support to the structure and brace the track 1001 out-of-plane, as best seen in
Both the stay cables 1004 and connection cables 1003 are pre-stressed with an initial tension to remove the sag due to the self weight of the cable, which serves to stiffen the cable. The relationship between the amount of force in a cable and its axial stiffness is such that there is a steep drop-off in cable stiffness once the force in the cable drops below 25% of its design capacity. Therefore, it is recommended that the stay cables 1003 have a minimum pre-stress force of roughly 40% of their design load to avoid the rapid decrease in stiffness as cables are unloaded on the leeward side of the structure. This pre-stress force may also be higher as required to keep the leeward cables from going slack under wind loading.
The location of the ground anchors for the stay cables were modeled at 20%, 30%, 40%, and 50% of the overall structure height (on each side of the closed loop frame) for various cable diameters. The results of this study show that regardless of cable diameter, a stay cable stance of about 40% on each side of the closed loop frame is optimum for the 300 foot (100 meters), 400 feet (122 meters), and 500 feet (153 meters) structure heights, with 30% being optimum for 200 foot (61 meters). This wider stance minimizes the vertical component of the stay cable forces, which lessens the impact on the rim structure.
In addition to bracing and lateral support, the connection and stay cables also help to relieve some of the demand on the rim structure. Depending on the shape of the closed loop frame, the structure may tend to “flatten out” to a more circular shape, which is resisted through bending of the plate girders. By pre-tensioning the spoke and stay cables strategically in a given track shape the cables begin to act as tension ties which resist the lateral thrust caused by the oval shape effect of the closed loop frame, relieving the bending demands on the plate girders and allowing them to act more as purely compression members.
By strategically employing tensioned cables at the appropriate parts of the frame an embedded tied arch can be created within the frame, allowing a significant reduction in the amount of structural steel needed to form a stable frame. This results in considerable cost savings. The prior art relies on a tensioned ring similar to a bicycle wheel with spokes attempting to share the load equally between the spokes even though the loads are not uniform. The tied arch concept employs larger horizontal tension elements 7000 installed horizontally at or near the mid-point of the frame 1001 and reduced size connection cables 1003 at all other locations where the loads are less, significantly reducing weight and the resulting cost, as seen in
The horizontal tension cables 7000 could either run as one or more cables from one side of the loop to the other, or could mount into the hub 1005 extending horizontally, so long as the cables are sized and tensioned to take the load of stress and create a functional tied arch within the closed loop of the track 1001. These cables would act as pure tension ties, relieving the plate girder bending stress without having a vertical component penalizing the upper half of the frame. Utilizing these horizontal tension cables 7000, the strain on the other connection cables 1003 is reduced. This reduced tension allows the other connection cables to be reduced in size. The connection cables 1003 can be 10 to 20 percent smaller, 10 to 30 percent smaller, 10-40 percent smaller or 10 to 50 percent smaller than the horizontal tension cables 7000 when this type of construction is utilized.
Currently it is believed that ASTM A-586 spiral strand cable would be most suited for the cables because of its axial stiffness properties. Typically, 1 inch (2.54 cm) diameter strands will be used for connection cables 1003, with the possibility of using larger cables in certain locations where warranted by the force level as noted above. For the stay cables 1004, 1.5 inch (3.81 cm) strands would likely be used for the 200 foot (61 meters) and 300 foot (100 meters) options, while 2 inch (5.08 cm) strands would be more likely for the taller structures due to an increase in overturning forces and a need for greater lateral stiffness.
a shows the track 1001 with just the stay cables 1004 and the ground anchors 1006 shown. The track has a first face 7006 and a second face 7007 and the rim structure can be vertically divided into a first half A and a second half B. The stay cables 1004 that attach to a given half of the track A are anchored on the ground anchors 1006 on the opposing half of the track B. This means that the stay cables 1004 are cross bracing the frame 1001, not just providing lateral support. This is repeated on the other face 7007. The center stay cables 1004a attach at the center top point of the track C. The ground anchors 1006 are spaced apart in a generally rectangular configuration around the rim structure such that two are on the first half side and two are on the second half side. The stay cables that are attached to the first face 7006 and first half A are attached to the ground anchor 1006a on the first face 7006 second half B side. The stay cables 1004 being attached to the first face 7006 and second half B being attached to the ground anchor 1006b on the first face 7006, first half A side. The stay cables 1004 being attached to the second face 7007 and first half A being attached to the ground anchor 1006c on the second face 7007, second half side B. The stay cables 1004 being attached to the second face 7007 and second half B being attached to the ground anchor 1006d on the second face 7007, first half A side. This ensures that the stay cables 1004 are cross braced to provide lateral stability and some of the compression load of the rim structure. This provides further stability to the structure.
As seen in
Referring next to
A set of distance measuring laser sensors (not shown) can be used to monitor the progress of the rider carriages 110 as these pass through the boarding/disembarkation area 1301 and report any over-speed to the Emergency Stop (E-Stop) system. This system can stop the ride in the event of any over-speed conditions. When the ride is fully loaded or evenly loaded the drive can be accelerated to about 135 feet per minute (13.5 meters per minute) for emergency situations. The direction of travel can also be reversed. If a faster ride is desired at a given location, then the ride 1000 could be either stopped for passenger loading or slowed. Passengers 1302 disembark the rider carriages 110 by stepping out of the moving rider carriage onto the loading platform for exiting. If needed ride operator can stop the motion of the ride 1000 to allow loading and disembarking of disabled passengers. The platform 1301 and rider carriages 110 are designed to be wheel chair accessible in the depicted embodiment. The control of passenger access to the loading and unloading area is well known the amusement ride industry and will not be discussed.
The depicted embodiment has a stationary passenger loading platform. If desired integrating a moving sidewalk into the loading platform may be advantageous to allow increased gondola speed and thus increased throughput.
The support carriages 1110 are epoxy coated steel frames about 12 feet (3.7 meters) in length wheel pivot point to wheel pivot point in the depicted embodiment. The support carriages 1110 are constructed in two parts. The base frame 1150 includes the pivoting drive wheel assemblies 1140, trolley drive controls 1800, tie cable clamps 1130, power pick-up assemblies 1120, data pick-up assemblies (not shown), and power distribution panels 1900. A pair of redundant, continuous power feed busses 1901 run around the perimeter of the track 1001. In the depicted embodiment the power feed bus 1901 is 480 volts AC (alternating current). The power feed bus 1901 needs to supply sufficient power for operating the ride; the exact amount of power supplied will depend on the specific installation. The power pick-up assemblies 1902 connect the power feed bus 1901 and then distribute the power to the carriage assemblies via slip-ring assemblies (not shown). Each rider carriage assembly has a power requirement of about 6 kilowatts in the depicted embodiment. The rider carriages 110 can be equipped with interior lighting that can produce adequate lighting at all locations within the rider carriage 110 for purposes of cleaning, servicing, and loading/disembarking at night. The rider carriages 110 are also equipped with lower intensity lighting for the night time ride and viewing. Each rider carriage can have an area standard electrical outlet that can activated only for purposes of servicing or cleaning. The base frame 1150 is connected to the side frames 1160 by four pinned connections discussed below.
The operator control center (OCS) located at or near the rider loading area 1300 can have an industrial computer and monitor running a software program that allows the operator to interact with a Programmable Automation Controller (PAC) also installed at this location. This PAC communicates with an on board PAC mounted on in the rider carriages 110. Data and communications is distributed from this on-board PAC to the OCS PAC via either a wave guide, “leaky cable” system, wireless, or enclosed copper bus bar system. The on-board PAC communicates with the trolley drive controls 1800 and other remote devices and sensors via an industrial Local Access Network (LAN). The PAC monitors and controls all aspects of the ride motion with supervisory input from the software and reports the ride condition back to the operator.
There is one trolley drive control 1800 located on each support carriage 1110 that controls speed of the eight 3 phase 480 volt AC drive motors in the depicted embodiment. The trolley drive control 1800 can also continuously monitor the motor performance and report the status to the PAC and the controller. The trolley drive controls 1800 enable the drive system to accelerate and decelerate at a smooth controlled rate and to accelerate to a higher than normal speed for fast evacuation, should this be necessary.
Referring next to
The drive wheel assembly 1140 must have sufficient structural rigidity to take the stress of the rotational force drive motors 1143 and the weight of the trolley assembly as the ride moves around the track. The various cross bracing 1167 depicted is way to provide such structural rigidity. Other possible configurations of the drive wheel assembly 1140 structure are possible, so long as they provide the necessary stability. There are two 10″ (25.4 cm) outside diameter by 3″ (7.6 cm) wide, polyurethane tread, traction drive wheels 1141 rotationally mounted on the inner frame 1146 of each wheel assembly 1140 in the depicted embodiment. Each of these drive wheels 1141 is driven by a ¾ horsepower 480 volts AC electric parallel shaft helical gear motor 1143 with brake in the depicted embodiment. This is done to allow for greater redundancy and to ensure that the failure of a single motor does not affect the operation of the ride. In principle, a single motor could be used to drive more than one wheel using a transmission system, but this believed to not be optimal. The four drive wheel assemblies 1140 are controlled by the trolley drive controls 1800 on each carriage. Thus, each rider carriage 1110 has eight drive wheels 1141 and a total drive of six horsepower. The system is designed to remain operational with up to 10 percent of the drives out of service. Each drive wheel 1141 produces about 100 Newtons of drive force for a total drive force of 800 N per trolley. The drive wheels 1141 are oriented to take load radial to the rim curvature and ride on the inside surface 1123 of the first flange 1022 of the plate girders of the rim structure.
The drive wheel motors 1143 are driven by the trolley motor controls 1800 such that the motor speed can be ramped up and down to produce very smooth starts and stops. The VFDs (variable frequency drives) are also used to limit the maximum torque output of the motors to 1.5 times the full load torque output of the motors. Likewise the brakes can be sized to limit the braking and holding force of the drive train. Thus, each drive wheel can generate a maximum of about 150 N of dynamic braking, drive, friction braking, or holding force in the depicted embodiment. Other amounts of force may be needed in other installations, and the motors would need to be chosen appropriately for the installation. No limitation as to the types and power of motors disclosed is intended or should be inferred. The drive system maximum speed is 27 miles per hour when loading and unloading. When the ride is fully loaded or evenly loaded the drive can be accelerated to about 40 miles per hour for emergency situations. The direction of travel can also be reversed. These drive options can be used by the operator to minimize the time required to bring any single passenger back to the passenger platform in the event that they become ill or otherwise need to be retrieved under emergency conditions.
There are a multitude of trolleys with each trolley having eight drive wheels in the depicted embodiment. Thus, this system provides an extraordinary level of drive redundancy. Up to 10 percent of the drives can be disabled and the ride can function normally as depicted. This arrangement provides a highly reliable drive system.
There is one approximately 7″ (17.8 cm) outside diameter by 4″ (10.16 cm) wide, urethane tread, guide wheel 1142 mounted in bracket 1148 on the inner frame 1146 of each wheel assembly 1140 in the depicted embodiment. Other suitable sizes and materials could be used as well; no limitation to the disclosed embodiment is intended or should be inferred. The guide wheel 1142 is located between the drive wheels 1141 in the depicted embodiment. The guide wheels 1142 are oriented to take load perpendicular to the plane of the closed loop frame and ride on the inside surface of the web of the plate girders 1002 of the rim structure. The guide wheels 1142 help to prevent shifts in the load of the frame 1160 from causing the drive wheels 1141 to press up against the plate girders 1002 as best seen in
There are two 12″ (30.48. cm) outside diameter by 4″ (10.16 cm) wide, polyurethane tread, radial wheels 1144 mounted in the outer frame 1147 of each wheel assembly in the depicted embodiment. The radial wheels 1144 are oriented to take load radial to the rim curvature and ride on the outer surface 1124 of the first flange 1022 of the plate girders 1002 of the rim structure.
As seen in
Referring next to
In the depicted embodiment the emergency access carriage 3080 has an epoxy coated steel frame that is configured to have its floor surface level with the rider carriage 110 when it is positioned next to the rider carriage 110. The emergency access carriage 3080 is sized to hold 8 passengers and one operator safely in the depicted embodiment. The frame is also coated steel in the depicted embodiment. The base frame 3040 and the support frame 3090 are configured such that the emergency access assembly 3000 does not come into contact with the rider trolleys while the emergency access assembly 3000 moves around the track 1001 or as the emergency access assembly 3000 is being brought alongside the rider trolley.
The emergency access carriage 3080 is mounted on axle 3110 on gimbaled bearings 1180. The emergency access carriage 3080 has side panels 3081 in the depicted embodiment. The choice of transparent or opaque side panel 3081 is a purely a design choice and may vary from installation to installation. The axle 3110 extends from the support frame 3090 as can be seen in
If desired more than one emergency access assembly 3000 could be provided per ride 1000, or the single emergency access assembly 3000 could have an emergency access carriages 3080 on each side of the support frame 3090, possibly allowing two rider carriages to be evacuated, one after another, before returning the loading area to unload the passengers.
The emergency access assembly 3000 is powered by a completely separate set of drive assemblies 3050 mounted on base frame 3040 seen in
The support frame 3090 is mounted on to track 1001 on second flange 1025 of girder 1002 with drive assemblies 3050 as seen in
The motors and wheels are mounted in a first frame 3053 and second frame 3054 which are attached to the base frame 3040 of the emergency access assembly 3000. The frames 3053 and 3054 are held together by compression unit 3055 seen in
Idler wheel set 6000 is behind the driven wheels 3051 in the depicted embodiment. The idler wheel set provides the counter balance to the forces created by the compression of the driven wheels against the track 1001 and provide for greater stability of the frame 3090. In the depicted embodiment there are four 10″ (25.4 cm) outside diameter by 3″ (7.62 cm) wide, polyurethane tread, radial wheels 6001 mounted on plate 6002 in the depicted embodiment. The radial wheels 6001 are oriented to take load radial to the rim curvature and ride on the outer surface 1124 of the second flange 1025 of the plate girders 1002 of the rim structure. A guide wheel 6003 is located between the radial wheels 6001 in the depicted embodiment. The guide wheels 6003 are oriented to take load perpendicular to the plane of the closed loop frame and ride on the outside surface of the web of the plate girders 1002 of the rim structure. The guide wheels 6003 help to prevent shifts in the load of the frame 3040 from causing the drive wheels 3051 to press up against the plate girders 1002
The emergency access carriage 308 discussed above can be used with prior art types of Ferris wheels with some modification, as see in
A gangplank (not shown) is used to connect the emergency access carriage 308 and the rider carriage 614 to allow the riders to transfer to the emergency access carriage 308 during an evacuation. If desired the gimbaled bearings 606 can have locking mechanisms (not shown) to lock the emergency carriage 308 to prevent or reduce motion of the carriages during the rider transfer. Extendable guard rails (not shown) could be provided as well.
A gangplank (not shown) is used to connect the emergency access carriage 308 and the rider carriage 615 to allow the riders to transfer to the emergency access carriage 308 during an evacuation. If desired the gimbaled bearings 606 can have locking mechanisms (not shown) to lock it to both the emergency carriage 308 and the rider carriage 615 to prevent or reduce motion of the carriages during the rider transfer. Extendable guard rails (not shown) could be provided as well.
While a number of exemplary aspects and embodiments have been discussed above, those of skill in the art will recognize certain modifications, permutations, additions and sub-combinations therefore. It is therefore intended that the following appended claims hereinafter introduced are interpreted to include all such modifications, permutations, additions and sub-combinations are within their true spirit and scope. Each apparatus embodiment described herein has numerous equivalents.
The terms and expressions which have been employed are used as terms of description and not of limitation, and there is no intention in the use of such terms and expressions of excluding any equivalents of the features shown and described or portions thereof, but it is recognized that various modifications are possible within the scope of the invention claimed. Thus, it should be understood that although the present invention has been specifically disclosed by preferred embodiments and optional features, modification and variation of the concepts herein disclosed may be resorted to by those skilled in the art, and that such modifications and variations are considered to be within the scope of this invention as defined by the appended claims. Whenever a range is given in the specification, all intermediate ranges and subranges, as well as all individual values included in the ranges given are intended to be included in the disclosure.
In general the terms and phrases used herein have their art-recognized meaning, which can be found by reference to standard texts, journal references and contexts known to those skilled in the art. The above definitions are provided to clarify their specific use in the context of the invention.
This application is a non-provisional application claiming the benefit of provisional application No. 61/239,852; filed Sep. 4, 2009 and provisional application No. 61/295,000; filed January 14, both of which are hereby incorporated by reference for all purposes.
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PCT/US2010/047986 | 9/7/2010 | WO | 00 | 6/18/2012 |
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WO2011/029093 | 3/10/2011 | WO | A |
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Silberman v. Kitchen, Appellant's Motion for Rehearing and/or Reconsideration, District Court of Appeal of Florida, Third District, Case No. 3D12-859, Jul. 6, 2012. |
Silberman v. Kitchen, Appellee's Response in Opposition to Appellant's Motion for Rehearing/Reconsideration of Order Denying Motion to Relinquish Jurisdiction, District Court of Appeal of Florida, Third District, Case No. 3D12-859, Jul. 10, 2012. |
Silberman v. Kitchen, Order Granting Motion for an Extension of Time and Denying Rehearing, District Court of Appeal of Florida, Third District, Case 3D12-859, Jul. 11, 2012. |
US Thrillrides v. Uni-Systems, Order Overruling Respondent's Jurisdictional Objections, American Arbitration Association, Case No. 33517Y0002712, Jul. 17, 2012. |
Silberman v. Kitchen, Appellant's Initial Brief, District Court of Appeal of Florida, Third District, Case No. 3D12-859, Jul. 20, 2012. |
Uni-Systems v. US Thrillrides, Memorandum of Law Opposing Defendant's Motion to Dismiss and Consenting to Stay of Action Pending Arbitration, US District Court Northern District of Florida, Case No. 4:12-cv-00165, Jul. 23, 2012. |
Kitchen v. Silberman, Order Denying in Part Plaintiffs Motion to Dismiss Counterclaims, Circuit Court of the 11th Judicial Circuit, Miami-Dade County, FL, Case No. 12-03667CA20, Sep. 12, 2012. |
Uni-Systems v. US Thrillrides, Joint Stipulation for Dismissal with Prejudice, US District Court Northern District of Florida, Case No. 4:12-cv-00165, Nov. 1, 2012. |
Kitchen v. Silberman, Stipulation of Dismissal, District Court of Appeal of Florida, Third District, Case No. 3D12-859, Nov. 8, 2012. |
US Thrillrides v. Uni-Systems, Joint Stipulation for Dismissal with Prejudice, American Arbitration Association, Case No. 33517Y0002712, Nov. 14, 2012. |
Kitchen v. Silberman, Hearing Transcript, Circuit Court of the 11th Judicial Circuit, Miami-Dade County, FL, Case No. 12-03667CA20, Feb. 27, 2012. |
Extended European Search Report dated May 8, 2013 for related case EP 10814626.7. |
Number | Date | Country | |
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20120277008 A1 | Nov 2012 | US |
Number | Date | Country | |
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61239852 | Sep 2009 | US | |
61295000 | Jan 2010 | US |