Patent Grant
7597050
The present invention relates to a return system for returning a crane to a home position upon loss of power to the crane.
Conventional overhead cranes include a frame with a pair of bridge cross members that move along a pair of main support beams. A pair of rails are supported by the cross members and a hoist moves along the pair of rails in a direction transverse to the main support beams. Some cranes are used to store and retrieve containers holding radioactive materials or other hazardous materials. Oftentimes, the containers are stored within tunnels inside a mountain or other facility that people cannot enter and the crane transports the containers to and from storage positions within the tunnels. Because of the hazardous nature of the container contents and the tunnels, there is a barrier sealing the tunnel that people cannot pass. Once the crane passes the barrier, it could become stranded due to power failure, power loss to the crane, or failure of a component within the crane. As a result, no one can reach the crane to repair it due to the hazardous nature of the tunnels.
One retrieval solution uses a rope or chain, with one end attached to the crane and another end located outside the barrier, to pull the crane back to a home position or a position outside the barrier where repairs can occur. However, due to the tunnel length, use of a rope to pull the crane back is not feasible or efficient. Further, the crane may not be able to roll back to the barrier because of the power loss. Another solution uses another device that moves along the rails to retrieve the crane, however, this solution is also limited if the crane cannot roll due to the power loss.
In one embodiment, the invention provides a crane return system for returning a crane component to a home position when there is a loss of power. A crane includes a bridge adapted to travel along at least one rail and includes a plurality of main wheels to travel along the rail. The crane return system includes a plurality of auxiliary drive wheels supported by the bridge, the auxiliary drive wheels movable between a first position, in which the auxiliary drive wheels are recessed from the rail, and a second position, in which the auxiliary drive wheels are in contact with the rail, wherein when power is supplied to the crane return system the auxiliary drive wheels are in the first position. The crane return system includes a hydraulic fluid pressure vessel for storing hydraulic fluid, wherein a substantially fixed mass of hydraulic fluid is contained within the crane return system, and a hydraulic cylinder interconnected with the auxiliary drive wheels and selectively fluidly communicating with the hydraulic fluid pressure vessel. When power is lost to the crane, hydraulic fluid is supplied to the hydraulic cylinder to extend the hydraulic cylinder and thereby move the auxiliary drive wheels from the first position to the second position. A drive motor is interconnected with the auxiliary drive wheels and selectively fluidly communicates with the hydraulic fluid pressure vessel, wherein when the auxiliary drive wheels are in the second position, hydraulic fluid is diverted from the hydraulic cylinder and supplied to the drive motor to rotate the auxiliary drive wheels and move the bridge toward a home position.
In another embodiment, the invention provides a crane comprising a bridge adapted to travel along a pair of rails, the bridge including a plurality of main wheels and a plurality of auxiliary drive wheels. The auxiliary drive wheels are movable between a first position, in which the auxiliary drive wheels are recessed from the rails when power is supplied to the crane, and a second position, in which the auxiliary drive wheels are in contact with the rails when power is off to the crane. The crane also includes a hydraulic fluid pressure vessel filled with hydraulic fluid and a hydraulic cylinder interconnected with the auxiliary drive wheels and selectively fluidly connected with the hydraulic fluid pressure vessel. When power is lost to the crane, hydraulic fluid is delivered from the hydraulic pressure vessel to the hydraulic cylinder to extend the hydraulic cylinder and thereby move the auxiliary drive wheels from the first position to the second position. A drive motor is interconnected with the auxiliary drive wheels and selectively fluidly connected with the hydraulic fluid pressure vessel, wherein when the auxiliary drive wheels are in the second position, hydraulic fluid is diverted from the hydraulic cylinder and delivered from the hydraulic fluid pressure vessel to the drive motor to rotate the auxiliary drive wheels and move the bridge toward a home position.
In another embodiment the invention provides a method of returning a crane component to a home position upon a loss of power to the crane. A crane includes a bridge adapted to travel along at least one rail with a plurality of main wheels in contact with the rail and a plurality of auxiliary drive wheels recessed from the rail. The method includes supplying and storing hydraulic fluid in a hydraulic fluid pressure vessel. Upon a loss of power to the crane, hydraulic fluid is supplied from the hydraulic fluid pressure vessel to a hydraulic cylinder interconnected with the auxiliary drive wheels, the hydraulic cylinder extending to move the auxiliary drive wheels into contact with the rail. Hydraulic fluid is supplied from the hydraulic fluid pressure vessel to a drive motor when the auxiliary drive wheels contact the rail to drive the auxiliary drive wheels such that the bridge travels along the rail toward the home position, wherein hydraulic fluid is diverted from the hydraulic cylinder. Flow of hydraulic fluid is stopped to the drive motor when the bridge reaches the home position to thereby stop the auxiliary drive wheels.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
In the illustrated embodiment, top surfaces of the first and second main support beams 22 define rails 26 that the bridge 18 travels along. The bridge 18 includes a first girder 30, a second girder 34, and a pair of end trucks 38 that extend between the first and second girders 30, 34 (only one end truck 38 is shown in
The end truck 38 shown in
The first and second girders 30, 34 are spaced apart from each other and generally parallel. The girders 30, 34 are aligned transversely to the main support beams 22. A trolley 54, or second bridge, travels along girder rails 58, 62 that are positioned on top surfaces of the first and second girders 30, 34. The trolley 54 includes a pair of end trucks 66, 70 that are aligned generally parallel to the first and second girders 30, 34. Each end truck 66, 70 defines a passage for receiving one of the girder rails 58, 62. Wheels (not shown) are disposed in each passage to facilitate travel of the trolley 54 along the rails 58, 62. As will be readily known to those of skill in the art, any number of driven wheels may be disposed in the end trucks 66, 70. Further, idle wheels may be disposed in the end trucks 66, 70 to facilitate travel of the trolley 54 along the first and second girders 30, 34. As discussed below, in a further embodiment the end trucks 66, 70 each include an auxiliary end truck with movable auxiliary drive wheels. As used herein, bridge is a movable carriage of the crane and includes the main bridge, the trolley carrying the hoist, or the like.
The hydraulic fluid pressure vessel 84 stores hydraulic fluid, wherein a substantially fixed mass of hydraulic fluid is contained within the crane return system 80. The hydraulic cylinders 88 are coupled to the auxiliary end truck 46 and fluidly communicate with the fluid pressure vessel 84. When the cylinders 88 extend, the auxiliary end truck 46 moves toward the rail 26 to thereby move the auxiliary drive wheels 50 to the second position and bring the wheels 50 in contact with the rail 26. When the cylinders 88 retract, the auxiliary end truck 46 retracts away from the rail 26 to thereby move the auxiliary drive wheels 50 to the first position and recess the wheels 50 from the rail 26. A normally-closed power loss valve 104 regulates flow of hydraulic fluid from the fluid pressure vessel 84 to the cylinders 88.
The hydraulic drive motor 100 is electrically connected to the auxiliary drive wheels 50 and fluidly communicates with the hydraulic fluid pressure vessel 84. When the drive motor 100 receives hydraulic fluid from the fluid pressure vessel 84, the drive motor 100 causes rotation of the auxiliary drive wheels 50 to move the bridge 18 along the rails 26 of the main support beams 22. A wheel down valve 108 regulates flow of hydraulic fluid from the fluid pressure vessel 84 to the drive motor 100 and flow of hydraulic fluid from the fluid pressure vessel 54 to the hydraulic cylinders 88. The wheel down valve is shown as a three-way valve in
The hydraulic fluid reservoir 92 fluidly communicates with the hydraulic cylinders 88, the hydraulic drive motor 100, and the hydraulic fluid pressure vessel 84. The fluid reservoir 92 receives hydraulic fluid from the cylinders 88 and the drive motor 100 and stores the hydraulic fluid until the pump 96 pumps the hydraulic fluid to the fluid pressure vessel 84. A normally-closed system reset valve 116 directs flow of hydraulic fluid from the fluid reservoir 92 to either the fluid pressure vessel 84 or the cylinders 88.
In
Force from the auxiliary drive wheels 50 contacting the rail 26 lifts the main wheels 42 from contact with the rail 26 and the main end truck 38 retracts from the rail 26. Hydraulic fluid is delivered to the hydraulic drive motor 100 from the hydraulic fluid pressure vessel 84, via the wheel down valve 108. The hydraulic fluid energizes the drive motor 100, which rotates the interconnected auxiliary drive wheels 50 to thereby move the bridge 18 along the rails 26 of the main support beams 22 and towards the home position. In the illustrated embodiment, the drive motor 100 is supported by the auxiliary end truck 46.
During this phase of the crane return, the home position valve 112 and the system reset valve 116 remain in the respective initial position. The home position valve 112 remains open to permit hydraulic fluid to flow from the hydraulic drive motor 100 to the hydraulic fluid reservoir 92, whereby the pump 96 pumps hydraulic fluid back to the hydraulic fluid pressure vessel 84. The system reset valve 116 remains positioned to prevent hydraulic fluid from the fluid reservoir 92 from flowing to the hydraulic cylinders 88.
A hydraulic fluid flow path 142 is shown by the solid, bold line in
During this phase of the crane return, the normally-closed system reset valve 116 is actuated open, i.e., to a second position, such that hydraulic fluid flows between the hydraulic fluid reservoir 92 and the hydraulic cylinders 88. The pump 96 pumps hydraulic fluid from the fluid reservoir 92 to the cylinders 88, which thereby retract to pull the auxiliary end truck 46 and the auxiliary drive wheels 50 away from the bridge rail 26. After the hydraulic fluid cycles through the cylinders 88, the hydraulic fluid returns to the fluid reservoir 92. A hydraulic fluid flow path 148 is shown by the solid, bold line in
Once the auxiliary drive wheels 50 are lifted from contact with the rail 26, the force lifting the main end truck 38 and the main wheels 42 from the rail 26 is released. Thereby, the main end truck 38 returns to its initial position and the main wheels 42 are in contact with the rail 26 to travel along the rail 26 and move the bridge 18 along the main support beams 22. Once the main wheels 42 and the auxiliary drive wheels 50 return to the respective initial positions, the system reset valve 116 is actuated back to its initial closed position, whereby hydraulic fluid cannot flow between the hydraulic fluid reservoir 92 and the hydraulic cylinders 88. This phase of the crane return is illustrated in
The crane return system 80 discussed above is described for use when a loss of power occurs to the crane 10, such as when there is a power failure to the crane 10 or power is purposefully cut to the crane 10 (e.g., when mechanical failure occurs or a crane component breaks) so that the crane return system 80 will automatically return the crane 10 to the home position. Once power is restored to the crane 10 (e.g., power is turned back on or necessary repairs are completed on the crane), the crane return system is reset and disabled, and the crane 10 will operate with its main components.
The crane return system 80 facilitates retrieval of a disabled crane from areas that people cannot enter because of radioactive or hazardous material. In particular, when power is lost to the crane 10, the crane return system 80 is able to operate and return the crane 10 to a home position because the crane return system 80 does not rely upon electrical power. Instead, the crane return system 80 uses potential energy converted to kinetic energy through the storage of pressurized hydraulic fluid. The valves are mechanically actuated such that a retrieval sequence is activated to return the crane 10 to a home position.
The embodiment of the crane return system discussed above describes one auxiliary end truck interconnected with one main end truck of the crane bridge. However, it should be readily apparent to one of skill in the art that each main end truck of the bridge includes an auxiliary end truck positionable by the crane return system to move the bridge upon a loss of power. In a further embodiment of a crane including a trolley (or second bridge), the crane return system includes auxiliary end trucks with auxiliary drive wheels interconnected with the trolley end trucks. Thus, upon a loss of power, the crane return system positions the auxiliary drive wheels to move the trolley to a home position using the crane return system and sequence of operations described above. The present invention crane return system can be adapted for use with any number of types of cranes for returning a crane to a home position.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US2005/027282 | 8/1/2005 | WO | 00 | 1/6/2006 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2007/015693 | 2/8/2007 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 894916 | Strobel et al. | Aug 1908 | A |
| 3192119 | Hosegood et al. | Jun 1965 | A |
| 3972420 | Stock et al. | Aug 1976 | A |
| 4576100 | Zanin | Mar 1986 | A |
| 4597497 | Aberegg | Jul 1986 | A |
| 4635802 | Hylton | Jan 1987 | A |
| 4718539 | Fukuwatari et al. | Jan 1988 | A |
| 4730743 | Rosman | Mar 1988 | A |
| 4836111 | Kaufmann | Jun 1989 | A |
| 20040026349 | Colgate et al. | Feb 2004 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 20070125258 A1 | Jun 2007 | US |
