| 摘要 |
An example robotic method for disassembling and removing a well string (e.g., a string of sucker rods or tubing within a wellbore) involves a computer controlled track and trolley system. Movement of multiple trolleys, carriages, shuttles, articulated arms and other hardware is orchestrated in a manner that minimizes cycle time and thus reduces the overall time for removing the entire well string. In some examples, upper and lower robots travel along and share a first set of tracks while an upper trolley mechanism and a main trolley travel along and share a second set of tracks. In some examples, the two sets of tracks are mounted vertically to a mast, wherein the mast is part of a workover vehicle. |
| 主权项 |
1. A method for removing a well string from within a well bore at a well site, wherein the well site includes a pumpjack with a walking beam and a horse head, the well bore defines a longitudinal centerline and the well string when assembled comprises a plurality of shafts interconnected end-to-end, the plurality of shafts includes at least an upper shaft having an upper shaft weight, a lower shaft having a lower shaft weight and a remaining well string below the lower shaft, the method involves the use of a wellhead slip at the well bore and a workover vehicle at the well site, the workover vehicle includes at least one of a tongs mechanism, a mast, a shaft storage area, a trolley track system, a main trolley with an elevator head, an upper trolley mechanism, a robotic system with an end effector, and a transfer track system, the workover method comprising:
leaving at least a portion of the pumpjack intact at the well site; driving the workover vehicle to the well site; parking the workover vehicle at the well site such that the longitudinal centerline is interposed between the workover vehicle and the portion of the pumpjack that is left intact at the well site, an imaginary vector pointing horizontally from the portion of the pumpjack that is left intact, passing through the longitudinal centerline toward the workover vehicle defines a forward direction and an imaginary horizontal line perpendicular to the forward direction defines a lateral direction; the wellhead slip clamping onto the upper shaft and supporting most of the upper shaft weight and the lower shaft weight; the elevator head capturing the upper shaft; the wellhead slip releasing the upper shaft; transferring most of the upper shaft weight and the lower shaft weight from the wellhead slip to the elevator head; the main trolley traveling upward along the trolley track system, thereby raising the well string and lifting the upper shaft out from within the well bore at a first peak velocity; the wellhead slip clamping onto the lower shaft; the main trolley momentarily lowering the well string while the well head slip is clamping onto the lower shaft; for a first period, the well head slip holding the lower shaft at a substantially constant elevation; while the upper shaft is above the wellhead slip, transferring most of the upper shaft weight and the lower shaft weight from the elevator head to the wellhead slip; the main trolley lowering the elevator head while the lower shaft is at the substantially constant elevation; the upper trolley mechanism traveling along the trolley track system; the upper trolley mechanism being at least partially above the elevator head and engaging the upper shaft; the tongs mechanism unscrewing a first joint connecting the upper shaft to the lower shaft; the main trolley lowering the elevator head while the tongs mechanism is unscrewing the first joint; the end effector gripping the upper shaft while the upper trolley mechanism is above the end effector and while the elevator head is below the end effector; after unscrewing the first joint and after gripping the upper shaft, the robotic system transferring the upper shaft from the longitudinal centerline of the well bore to the shaft storage area that is horizontally spaced apart from the longitudinal centerline, wherein the robotic system transferring the upper shaft from the longitudinal centerline of the well bore to the shaft storage area involves moving the upper shaft in translation in the forward direction and the lateral direction; the end effector releasing the upper shaft at the shaft storage area; the elevator head capturing the lower shaft; the wellhead slip releasing the lower shaft, thereby transferring most of the lower shaft weight to the elevator head; the main trolley lifting the remaining shaft string and thereby lifting the lower shaft out from within the well bore at a second peak velocity, wherein the second peak velocity is greater than the first peak velocity; the wellhead slip clamping onto the remaining shaft string; the main trolley momentarily lowering the lower shaft and the remaining shaft string while the well head slip is clamping onto the remaining shaft string; for a second period, the well head slip holding the remaining shaft string at a substantially fixed elevation; while the lower shaft is above the wellhead slip, transferring most of the lower shaft weight from the elevator head to the wellhead slip; the main trolley lowering the elevator head while the remaining shaft string is at the substantially fixed elevation; the upper trolley mechanism being at least partially above the elevator head and engaging the lower shaft; the tongs mechanism unscrewing a second joint connecting the lower shaft to the remaining shaft string; the main trolley lowering the elevator head while the tongs mechanism is unscrewing the second joint; the end effector gripping the lower shaft while the upper trolley mechanism is above the end effector and while the elevator head is below the end effector; after unscrewing the second joint and after gripping the lower shaft, the robotic system transferring the lower shaft from the longitudinal centerline of the well bore to the shaft storage area; and the end effector releasing the lower shaft at the shaft storage area. |
