Patent Grant
10479644
Embodiments described herein generally relate to elevator systems for supporting tubular members in the field of oil and gas production. The elevator systems have a fluid flowpath to provide fluid power in the elevator system.
In the oil and gas industry, it is the usual practice to hoist various types of tubular members, such as drill strings, production tubing, and other pipes, on rigs with various elevators of different capacities. The elevator system includes an elevator connected to a top drive that is used to support and move the tubular members by rotating, raising and lowering the tubular members. The elevator is connected to the top drive using a pair of elevator links that may be referred to as elevator bails. The elevator links provide a connection between the elevator and the top drive. The elevator may be rotated, tilted, raised and lowered using the elevator links connecting the elevator to the top drive.
The elevator system is powered by hydraulic power or electric power to hold and move the tubular members. The elevator system may also be equipped with sensors, including optical and electrical sensors. A number of control lines, including supply and signal lines, may be needed to provide power and communication to the elevator system. The control lines may be hoses or other conduits that may run from the rig floor to the elevator and/or the top drive located above the elevator. Oftentimes, the control lines get tangled, damaged, or in the way of or otherwise interfere with personnel and/or other rig equipment that can disrupt the operation of the elevator and/or the top drive.
Therefore there is a need for new and/or improved systems and methods that safely and efficiently provide power and communication for the elevator system.
Embodiments of the disclosure describe an apparatus and method for an elevator system that supports a tubular member used for production of oil and gas.
In one embodiment, an elevator system for supporting a tubular member comprises an elevator; a first elevator link connected to the elevator for supporting the elevator comprising a shaft having an upper shaft end and a lower shaft end; an upper eye coupled to the upper shaft end and having an upper eye body defining an upper eye opening; a lower eye coupled to the lower shaft end and having a lower eye body defining a lower eye opening; a first upper port and a first lower port disposed on the first elevator link; and a first internal passage extending through at least a portion of the shaft and in communication with the first upper port and the first lower port; and a second elevator link connected to the elevator for supporting the elevator.
In one embodiment, an elevator link configured to couple an elevator to a top drive for supporting a tubular member comprises a shaft having an upper shaft end and a lower shaft end; an upper eye coupled to the upper shaft end and having an upper eye body defining an upper eye opening; a lower eye coupled to the lower shaft end and having a lower eye body defining a lower eye opening; a first upper port and a first lower port disposed on the elevator link; and a first internal passage extending through at least a portion of the shaft and in communication with the first upper port and the first lower port.
In one embodiment, a method of supporting a tubular member with an elevator system comprises coupling a first control line to a first elevator link of the elevator system, wherein the first elevator link comprises a shaft, and a first upper port and a first lower port disposed on the elevator link, wherein a first internal passage extends through at least a portion of the shaft, and wherein the first internal passage is in communication with the first upper port and the first lower port; and pumping fluid through the first control line and through the first internal passage; and using the fluid as hydraulic power for the elevator system.
So that the manner in which the above recited features of the disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to implementations, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only selected implementations of this disclosure and are therefore not to be considered limiting of its scope, for the disclosure may admit to other equally effective implementations.
To facilitate understanding, identical reference numerals have been used, wherever possible, to designate identical elements that are common to the Figures. Additionally, elements of one implementation may be advantageously adapted for utilization in other implementations described herein.
Embodiments herein generally provide an elevator system with an elevator link having integrated control lines. The elevator system includes an elevator that is connected to a top drive by a pair of elevator links. At least one of the elevator links is configured to integrate control lines with the elevator link. A number of different control lines may be needed to provide hydraulic or electrical power and communication signals to the elevator system. The elevator link has at least one internal passage that extends longitudinally along the elevator link between a lower port formed at one end of the elevator link and an upper port formed at an opposite end of the elevator link. The internal passage may be used to extend a control line through the internal passage and through the lower port and the upper port of the elevator link. By using the internal passage of the elevator link, a plurality of control lines can be efficiently connected between the elevator and the top drive. Control lines forming loops and potentially becoming tangled or damaged during operation, for example by equipment external to the elevator link, is reduced.
As shown in
A first passage system 156 extends through the first elevator link 104 and a second passage system 158 extends through the second elevator link 106, as depicted by dashed lines in
First control lines 162 extend from a control unit 164 on the rig floor 116 to the first elevator link 104 and to the top drive 110. The embodiment of the elevator system 100 in
Second control lines 170 extend from the top drive 110 to the second elevator link 106. The second control lines 170 extend through the second passage system 158 of the second elevator link 106 and to the elevator 102. A second control unit 172 is attached to or disposed proximate the top drive 110. The second control line 170 may extend from the second control unit 172. The second control unit 172 may include a hydraulic power unit (HPU), pressurized gas unit, electric power unit, optical power unit or controller for sending and receiving signals. In some embodiments, the elevator system 100 may include only one passage system 156, 158 extending through one of the elevator links 104, 106. In some embodiments, the elevator system 100 may include only one control unit 164, 172.
The first control lines 162 and second control lines 170 may be formed by hoses or fluid conduits that transport pressurized fluid, electrical or optical communication lines, or electrical power transmission lines. In different embodiments, there may be one to ten control lines 162, 170. For example, the control lines 162, 170 may be used to provide hydraulic power to the elevator 102 to position the elevator doors 122 from an open position to a closed position for supporting a tubular member 120.
In some embodiments, the first control lines 162 are coupled to the first elevator link 104 so that one or more first fluid flowpaths may be formed between the elevator 102 and the top drive 110. The first fluid flowpaths formed by the first control lines 162 extend from the first control unit 164, through the first control line 162, through the first passage system 156, and to the top drive 110. The second control lines 170 are coupled to the second elevator link 106 so that one or more second fluid flowpaths may be formed between the top drive 110 and the elevator 102. The fluid flowpaths formed by the second control line 170 extends from the second control unit 172, through the second control line 170, through the second passage system 158, and to the elevator 102.
In some embodiments, transmission lines extend through the passage system 156, 158. The transmission lines may include electrical conductors for transmitting electrical signals. The electric signals transmitted may be for transmitting information signals or power. For example, the transmission lines may be used to provide electrical power to the elevator 102 to position the elevator doors 122 from an open position to a closed position for supporting a tubular member 120. For example, the transmission lines may be used to transmit signals between the first control unit 164 and a sensor 166 disposed on the elevator 102 and a sensor 168 disposed on top drive 110. The sensor 166 may be used to detect and signal to the first control unit 164 that the elevator doors 122 are in a closed position. The first control unit 164 may also transmit signals through the transmission lines to the top drive 110 to control operation of the top drive 110 and elevator 102. The sensor 168 disposed proximate the top drive 110 may be used to detect and signal to the first control unit 164 position information of the top drive 110. The elevator 102 and top drive 110 each may be equipped with a plurality of sensors 166, 168.
The top drive 110 may be used to raise, lower, or tilt the elevator 102 and supported tubular member 120. The transmission signals transmitted through the transmission lines passing through the first passage system 156 to the top drive 110 may be used to control the raising, lowering, or tilting of the elevator 102 by the top drive 110. For example, the first control unit 164 may transmit to the top drive 110 a signal through the transmission lines directing the top drive 110 to raise the elevator 102 in response to information from sensor 166 that the elevator doors 122 are closed.
The upper eye 136 may be coupled to the upper shaft end and the lower eye 138 may be coupled to the lower shaft end by any means, such as by welding two separate pieces together or by forging the eyes 136, 138 and the shaft 130 from a single piece of material. For example, the elevator links 104, 106 may be forged from a metallic material, and support the weight of the elevator 102 and the tubular member 120. The upper eye 136, the lower eye 138 and the shaft 130 of the elevator link 104 may be formed from one piece of material. When formed from one piece of material, the upper eye 136 is coupled to the upper shaft end and the lower eye 138 is coupled to the lower shaft end during a manufacturing process, such as a forging process.
The elevator link 104 may further include a plurality of port housings 186. Disposed proximate each lower port 182 is one of the port housings 186. In the embodiment shown, each port housing 186 is disposed on and extends outwardly from the link outer surface 178. Each port housing 186 surrounds one of the lower ports 182. The port housing 186 includes a port connector 190. The port connector 190 is in the form of a plurality of external threads. In other embodiments, the port connector 190 may be in the form of a plurality of internal threads, snap-on connectors, or other conventional connectors.
The port housings 186 may be used to connect the internal passages 184-1, 184-2 and the lower ports 182 to the first control lines 162-1, 162-2. The first control lines 162-1, 162-2 include a control line connector 194. The control line connector 194 has a plurality of internal threads that detachably connect to the port connectors 190. The first control lines 162-1, 162-2 may be in the form of fluid lines, for example hoses, that handle pressurized fluid flowing from the control units 164, 172. For example, pressurized fluid may flow from the first control unit 164 through the control lines 162-1, 162-2, and through the lower ports 182 to the internal passages 184-1, 184-2 that are in fluid communication with the control lines 162-1, 162-2. Fluid flow arrows 196 illustrate fluid flow through the internal passages 184 of the first elevator link 104. The internal passages 184-1, 184-2 and the control lines 162-1, 162-2 together form a fluid flowpath for flowing fluid between the elevator 102 and the top drive 110.
In one embodiment, a first control line 162-3 may be inserted through the internal passage 184-3. The first control line 162-3 extends through the internal passage 184-3 and extends through the port 182 and outwardly from the link outer surface 178. A port housing 186 may be attached proximate the port 182 and the first control line 162-3 extends outwardly from the port housing 186.
As depicted in
Referring to
A plurality of first control lines 162 extend through the internal passage 184 from one end of the shaft 130 to the other end of the shaft 130. In the embodiment shown, there are three first control lines 162. Each first control line 162 extends through a lower port 182. The plurality of first control lines 162 can be separated by having each first control line 162 pass through a lower ports 182 to reduce tangling of the first control lines 162 extending outwardly from the elevator link 604.
Port housings 186 are coupled to the shaft 130, as discussed with respect to
Referring to
In operation, the elevator system 100 is provides a method of supporting a tubular member 120. The elevator system 100 may use hydraulic power during an operation to secure and move the tubular member 120. For example, a first control line 162 is coupled to the first elevator link 104 of the elevator system 100. The first control line 162 is in fluid communication with one of the lower ports 182 and at least one of the internal passages 184. A fluid may be pumped through the first control line 162 and through the at least one internal passage 184 of the elevator link 104. The fluid may be pumped from the control unit 164. The fluid that is being pumped flows between the elevator 102 and the top drive 110. The second control line 170 may be connected to the second elevator link 106. The second control line 170 is in fluid communication with one of the upper ports 180 and at least one of the internal passages 185. A fluid may be pumped through the second control line 170 and through the at least one internal passage 185 of the elevator link 106.
The elevator system 100 uses the fluid as hydraulic power for the elevator system 100. For example, the fluid provided to the may be used as hydraulic power to move the elevator doors 122 between the open position and the closed position. The fluid may be used as hydraulic power to lower, raise, rotate, or tilt the elevator 102.
The elevator system 100 also may use electrical power, electrical communication signals, or optical signals during an operation to secure and move the tubular member 120. For example, the first control line 162 may be in the form of an electrical line that is inserted through the internal passage 184 and extends through the internal passage 184. The first control line 162 may provide a transmission path between at least one of the sensors 166, 168 and at least one of the control units 164, 172.
The elevator system 100 is configured to integrate the control lines 162, 170 with the elevator links 104, 106 to form an elevator link transmission path between the elevator 102 and the top drive 110. The use of the internal passages 184, 185 as part of the elevator link transmission path reduces the length of control lines 162, 170 disposed external to the elevator links 104, 106 in an unprotected location. Integrating the control lines 162, 170 with the elevator links helps reduce tangling or damage of the control lines 162, 170.
While the foregoing is directed to embodiments of the disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
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