Apparatus for automatically lubricating an oil well sucker rod stuffing box |
|||||||
申请号 | US14517546 | 申请日 | 2014-10-17 | 公开(公告)号 | US09605506B1 | 公开(公告)日 | 2017-03-28 |
申请人 | William Jameson; Ryan Utt; | 发明人 | William Jameson; Ryan Utt; | ||||
摘要 | A stuffing box lubrication system for oilfield pumping units automatically delivers to the stuffing box, at specified time intervals, a precise volume of lubricant. The stuffing box lubrication system has a grease reservoir, a pump, a controller, a high pressure hose and grease fitting, and a stuffing box which receives the grease. In situations where the stuffing box in use is not equipped with a ported inlet for receiving the grease, the present invention may further include a stuffing box adapter, having a ported inlet, where the stuffing box adapter couples with the stuffing box. | ||||||
权利要求 | What is claimed is: |
||||||
说明书全文 | This is a non-provisional application which claims priority to provisional patent application No. 61/892,337 filed on Oct. 17, 2013. The present invention generally relates to artificial lift systems which are utilized for production of fluids from subsurface reservoirs, including oil, water, and liquid phase hydrocarbons. More particularly, the present invention is utilized with artificial lift systems where a subsurface pump is actuated by a plurality of rods connected end-to-end, herein collectively referred to as a “rod string.” The rod string is set within a plurality of tubing joints likewise connected end-to-end, wherein the tubing joints are collectively referred to as a “tubing string.” Actuation of the subsurface pump lifts the fluid upwardly from the subsurface pump to the surface, where the fluids flow in the annular space between the rod string and the inside diameter of the tubing string as the fluid flows upwardly. There are generally three different types of subsurface pumps which can be actuated by rod strings, two which are positive displacement pumps, and the third is a roto-dynamic pump. The first type of subsurface pump is a plunger/barrel pump, wherein the reciprocal motion of the rod string reciprocates the plunger within the pump barrel, such that liquids are drawn into the pump barrel and lifted upwardly through the tubing string. The reciprocating motion of the rod string is typically imparted by a pump jack. The second type is a progressive cavity pump, wherein the rotational motion of the rod string operates a rotor which turns within a stator, and fluid is transferred by means of the progress through the pump of a sequence of small fixed shape cavities as the rotor is turned. In these systems, the rod string is rotated by a motor/gear reducer combination installed at the surface. The third type of pump, the roto-dynamic pump, is a centrifugal pump in which the rod string rotates a series of impellers. This type of system utilizes a similar motor/gear reducer combination as utilized for the progressive cavity system. For all of these systems, the uppermost rod in the rod string is a polish rod. The polished rod reciprocates in and out of, or rotates within, a stuffing box. The stuffing box is a close-fit assembly which cleans the polished rod, prevents debris from entering or exiting the well, and further prevents fluid from leaking from the well during operation. The stuffing box is typically mounted above a T-fitting at the top of the tubing. The stuffing box provides a dynamic seal along the length the polish rod. The stuffing box typically has a central passage through which the polish rod moves, while stuffing or packing material is compressed by an enclosing cap or fitting of the stuffing box which urges the packing material against the sides of the polish rod to create fluid seal. The packing materials are typically elastomers and other materials which are softer than the polish rod material. The movement of the polish rod within the packing material generates friction, and thus heat, which breaks down and degrades the packing materials. This process reduces the integrity of the seal formed between the packing material and the polish rod. In further aggravation, the presence of solids in the produced fluid, such as sand, can accelerate this degrading of the packing material as well as adversely impact the life of the polish rod. The loss of the integrity of the seal between the polish rod and the packing material will result in the escape of fluids from the well which can result in environmental damage and the loss of valuable resources, and can result in significant clean-up expense and potential fines and penalties. Accelerated packing replacement also requires the expenditure of man-hours which might otherwise be avoided. The lubrication of the polish rod and the packing material reduces the friction, and thus the heat, generated between the polish rod and packing material. This lubrication reduces the wear caused by movement of the polish rod within the packing material and extends the life of the packing and the polish rod. The typical lubricant used for this service is grease, which is typically placed in the interior of the stuffing box and carried by the polish rod into contact with the packing material. There are various proprietary lubricating greases which work particularly well for this service, where the greases may have enhanced mechanical and thermal stability, resistance to water, and corrosion resistance additives. Application of the lubricant is typically done by hand or by mechanically operated systems which continually apply a small dose of grease according to the motion of the walking beam of the pump jack, which may be connected with linkage or cable to a mechanical pump which strokes with the motion of the walking beam. While preferable to no lubrication at all, the manual lubrication requires the use of personnel, and can be overlooked and inconsistently applied. The mechanically operated systems are subject to failures in mechanical linkages, often have limited grease reservoirs, and may not deliver a consistent volume of grease into the stuffing box. The presently disclosed invention is an automated stuffing box lubrication system for oilfield pumping units. The invention provides a precise volume of lubricant to the stuffing box at specified time intervals as selected by the operator. The system comprises a large capacity grease reservoir which supplies grease to the stuffing box by a pump which is activated by a controller. The controller can be programmed to provide a precise volume of grease on a periodic basis. The grease is injected into the stuffing box through a high pressure hose and grease fitting. The controller, pump, pump motor, and grease reservoir may be contained within an enclosure cabinet, with the power supply and other electrical components contained within a segregated internal enclosure. The controller has user friendly controls for modifying the lubrication volume and intervals. The controller may be connected into a field wide supervisory control and data acquisition system so that status of the unit may be monitored. The grease reservoir may be equipped with level controls which annunciate a low level alarm when the reservoir is getting low. Power to the unit may be provided by solar panel or by low voltage (110 volt) alternative current sources. Referring now to the figures, As shown in The inventors herein have found that a HERCULES brand stuffing box with a ported inlet works well for this application, but other stuffing boxes may be utilized and the system may be adapted to work with different brands and types of stuffing box. As described in greater detail below, As shown in Reservoir 22 and controller 24 may come as an integrated unit such as the BRAVO pump packaged as manufactured by DROPSA or the G3 ELECTRIC LUBRICATION PUMP manufactured by GRACO. These units are not otherwise known to be used for lubrication of oilfield pumping unit stuffing boxes. The reservoir 22 may have a variable capacity ranging from approximately 70 ounces to 540 ounces of grease. Controller 24 may be programmed to dispense practically any volume of grease over a particular time frame, with a typical application ranging from 0.5 to 2.0 ounces of grease per day. The larger reservoir and relatively small volumes of injected grease thus have the capability of providing an extended grease supply before the reservoir requires refilling. The grease utilized with the device may be a variety of different greases and containing various additives, such as corrosion inhibitor. A grease manufactured by CHEMTOOL INCORPORATED known as ALPHA 2000, has been found to provide good service for this application. Controller 24 allows the lubrication cycle to be set up on a daily basis or other periodic basis, with a timer typically controlling the grease injection events. The actual pump time for the grease injection is usually quite brief, with a small volume of grease injected in each cycle. The controller 24 can provide a readout of the grease injection cycles over a particular period of time. The controller 24 can be connected to a field wide network, such as a supervisory control and data acquisition system (SCADA) system for providing reports of the amount grease injected over a period of time. The system may also provide an alarm upon the detection of critical operating conditions, such as when the grease level is low or when the grease injection system is not operating. An integrated reservoir 22—controller 24 is shown in As indicated in While the above is a description of various embodiments of the present invention, further modifications may be employed without departing from the spirit and scope of the present invention. Thus the scope of the invention should not be limited according to these factors, but according to the following appended claims. |