The present invention relates to gas compressors to be used with oil wells, and in particular to a piston rod seal assembly for use in a walking beam compressor and methods for manufacturing the same.
A common oil well pumping system includes a walking beam mounted upon a horizontally-axised, transverse pivot at the top of a Samson post. One end of the walking beam is connected to a pump rod and the other end is connected to the crank of a drive motor through a connecting rod. Rotation of the crank causes the walking beam to rock or oscillate in a vertical plane to raise and lower the pump rod. The rod-connected end of the walking beam is provided with the familiar “horse head” to keep the pump rod in alignment with the well axis. The opposite end of the walking beam carries a counterbalance weight to offset the weight of the pump rod and minimize the stress on the motor.
When pumping an oil well, both oil and gas may be produced and the capture of the gas is both profitable and better for the environment. Thus, an oil well pumping system can include a compressor unit mounted between the walking beam and a stationary part of the pumping unit for compressing the natural gas produced during the pumping of the oil. Such a compressor unit is called a walking beam compressor because it is activated by engaging a piston rod coupled to the walking beam. The rocking of the walking beam reciprocates the piston to effect intake and compression strokes. As a compressing mechanism compresses the gas, high pressures are created inside the compressor housing, requiring appropriate sealing elements between the compressor housing, the piston rod, and the atmosphere. Traditionally, a piston rod seal may have rubber sealing elements that tend to wear quickly and require replacement. Accordingly, there is a need for an improved piston rod seal assembly that can provide effective sealing between the walking beam compressor and the atmosphere while having an extended lifetime.
The present invention generally provides a seal for use in a piston rod seal assembly. In one embodiment, a stuffing box is provided having a cylindrical housing defining a lumen extending therethrough between top and bottom ends thereof. The lumen can be filled with an injectable fibrous sealant that is configured to form a seal around a piston rod extending through the bore and through the injectable fibrous sealant.
While various injectable fibrous sealant materials can be used, in one exemplary embodiment the injectable fibrous sealant is U-PAK® Injectable Sealant. The sealant can be pre-formed into a cylindrical seal having a bore formed therethrough and coaxial with the bore in the flange such that a piston rod can extend through the bore in the flange and through the bore in the cylindrical seal. In an exemplary embodiment, the bore formed in the cylindrical seal has a diameter that is less than a diameter of the bore formed in the flange.
The cylindrical seal can have a variety of configurations. In one embodiment, the cylindrical seal can be pre-disposed within the cavity, and any gaps formed between the cylindrical seal and an inner surface of the cylindrical housing are filled with additional injectable fibrous sealant injected into the lumen. In certain exemplary embodiments, the injectable fibrous sealant is under pressure when disposed within the lumen. The cylindrical seal can also include top and bottom pressure rings disposed on top and bottom end walls thereof and configured to prevent injectable fibrous sealant from leaking out of the lumen in the cylindrical housing. The top and bottom pressure rings can have, for example, a substantially A-shaped cross-section.
The cylindrical housing can also have a variety of configurations. In one exemplary embodiment, the top end of the housing can include a flange defining a bore coaxial with the lumen and having a diameter less than a diameter of the lumen. In another embodiment, the housing can include a plurality of holes extending therethrough between the top and bottom ends thereof for receiving a plurality of fastening elements therethrough. The housing can also include port can extend through the housing and configured to allow the injectable fibrous sealant to be injected into the cavity.
In another embodiment, an oil well pump is provided and includes a walking beam for pumping oil out of the ground, a piston rod mated to the walking beam, and a compressor disposed around the piston rod and configured to receive and compress gas contained with oil pumped out of the ground. An injectable sealant can be coupled to the compressor and concentrically positioned around the piston rod extending through the compressor to form a gas-tight seal around the piston rod.
In one exemplary embodiment, the injectable sealant can be U-PAK® Injectable Sealant. The piston rod extends through a bore formed in the injectable sealant, and the injectable sealant can be disposed within a stuffing box coupled to the compressor. The stuffing box can have a lumen formed therethrough that slidably receives the piston rod. In certain aspects, the injectable sealant can be pre-formed into a cylindrical sealing element having a bore formed therethrough that is co-axial with the lumen in the stuffing box and that for receives the piston rod. The cylindrical sealing element can pre-disposed within the stuffing box, and any gaps formed between the cylindrical sealing element and the stuffing box and piston rod are filled with additional injectable sealant injected into the stuffing box.
In other aspects, the stuffing box can include a top flange having a bore formed therein that receives the piston rod. In an exemplary embodiment, the bore in the flange has a diameter that is smaller than a diameter of the lumen in the stuffing box. The stuffing box can also include a plurality of fastener holes extending through a sidewall thereof, and/or a port extending through a sidewall thereof for delivering the injectable fibrous sealant into the lumen.
In other aspects, methods of manufacturing a piston rod seal assembly are provided, and in one embodiment the method can include forming a seal from an injectable fibrous sealant composition, positioning the seal within a housing, positioning a piston rod through the seal such that the piston rod is slidably movable relative to the housing and seal, and injecting additional injectable fibrous sealant composition into the housing to cause a pressurized seal to be formed around the piston rod. Injecting additional injectable fibrous sealant composition into the housing can fill all gaps between the seal, the housing, and the piston rod. In use, the seal can be configured to allow for longitudinal reciprocal movement of the piston rod therethrough while maintaining a gas-tight seal around the piston rod.
In one exemplary embodiment, forming a seal can include forming a cylindrical member having a bore formed therethrough. The cylindrical member can have a width from an outer surface to an inner surface thereof that corresponds to a distance between an interior wall of the housing and the piston rod. The method can also include mating top and bottom pressure rings to the seal. The pressure rings can prevent the injectable fibrous sealant composition from leaking out of the housing. Top and bottom washers can also be positioned adjacent to the top and bottom pressure rings. The method can further include coupling the housing to a compressor and coupling the piston rod to a walking beam that pumps oil out of the ground.
The invention will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings, in which:
Certain exemplary embodiments will now be described to provide an overall understanding of the principles of the structure, function, manufacture, and use of the devices and methods disclosed herein. One or more examples of these embodiments are illustrated in the accompanying drawings. Those skilled in the art will understand that the devices and methods specifically described herein and illustrated in the accompanying drawings are non-limiting exemplary embodiments and that the scope of the present invention is defined solely by the claims. The features illustrated or described in connection with one exemplary embodiment may be combined with the features of other embodiments. Such modifications and variations are intended to be included within the scope of the present invention.
The present invention generally provides a piston rod seal assembly for use in a walking beam compressor and methods for manufacturing the same. In general, the piston rod seal assembly includes an injectable fibrous sealant that is configured to form a seal around a piston rod movably disposed through a stuffing box in a walking beam compressor. The use of an injectable fibrous sealant is particularly advantageous as it allows a gas tight seal to be formed around the piston rod and between the walking beam compressor, the piston rod, and the atmosphere. Moreover, the injectable seal has an extended life relative to prior art rubber sealing elements.
As further shown in
In one embodiment as shown in
As further shown in
When assembled, the bottom end 204 can be configured to sit on top of the lower annular insert 94 and within the cylindrical cavity 92 formed in the cap 46, shown in
As shown in
As indicated above, the piston rod seal assembly 90 can also include a sealing element 232 disposed within the stuffing box 200. While the sealing element 232 can have various configurations and can be formed of any material known in the art able to withstand the pressurized environment while providing a lubricating seal around the piston rod 24, a particularly effective material for use in this way is an injectable fibrous sealant such as UPAK® Industrial Sealant manufactured by UTEX Industries, Inc. Thus, in one exemplary embodiment, the cylindrical sealing element 232 can be pre-formed of UPAK® Industrial Sealant and positioned inside the stuffing box 200 to provide a lubricating, fibrous, and solid material that is able to seal around the piston rod 24 within a pressurized environment. A sealing element 232 formed from an injectable fibrous sealant provides a seal that will have very low wear and will not require frequent replacement like rubber or composite seals. The sealing mechanism can be initially placed under pressure to form a gas-tight seal by injecting (e.g., through the port 218) additional sealant into the cavity and around the sealing element 232. Should any wear occur between the sealing element 232 and the piston rod 24, however, additional sealant can be injected into the cavity as needed and on multiple occasions to maintain required sealing pressures. This injecting of additional sealant can be performed “in the field” at the oil well pump, without having to disassemble the walking beam compressor. This is particularly time and cost effective and can thereby provide an extended lifetime for the piston rod seal assembly.
While many combinations of sealing mechanisms and components are possible, in the embodiment shown in
The top and bottom pressure rings 234, 236 can also be mated to other components within the sealing mechanism 230. In one embodiment, the top and bottom pressure rings 234, 236 can have a substantially A-shaped cross-section as shown in
Methods for manufacturing a piston rod seal assembly are also provided. In one embodiment, a seal is formed from an injectable fibrous sealant composition and positioned within a housing. A piston rod can be positioned through the housing and the seal such that the piston rod is slidably movable relative to the housing and seal. Additional injectable fibrous sealant composition can be injected into the housing to cause a pressurized seal to be formed around the piston rod.
More particularly, a housing or stuffing box can be machined into a generally cylindrical form. For example, as described in the exemplary embodiments above. In addition, a sealing mechanism can be assembled to be positioned inside the stuffing box. For example, a cylindrical sealing element can be pre-formed from an injectable fibrous sealant composition that is configured to provide lubrication and a pressurized seal around a piston rod. The cylindrical sealing element can be pre-formed to have a cylindrical size and shape that corresponds to a size and shape of an interior cavity within the stuffing box. The sealing mechanism can include other sealing components adapted to secure the cylindrical sealing element within the stuffing box. For example, as indicated above, annular pressure rings can be positioned on top and bottom surfaces of the cylindrical sealing element to prevent any additionally added sealant from leaking out when the system is placed under pressure. Top and bottom washers can be positioned adjacent to the pressure rings as described in detail above to facilitate seating the assembled sealing components inside the housing. Adapters can be included as needed between the bottom pressure ring and the bottom washer. The assembled sealing mechanism can be positioned inside the stuffing box to occupy the entire lumen in the stuffing box and form the assembled piston rod seal assembly. The sealing mechanism can be positioned inside the housing such that the top washer is positioned adjacent to a top flange portion of the stuffing box. The bottom washer can be positioned flush with the bottom end of the stuffing box.
The assembled piston rod seal assembly can be positioned adjacent to a lower annular insert within a top cap of a walking beam compressor and around a piston rod so that the piston rod is configured for reciprocal longitudinal movement therethrough relative to the piston rod seal assembly. Once the piston rod seal assembly is positioned adjacent to the lower annular insert, a fastening mechanism, such as retaining rods or bolts, can be inserted into receiving holes extending through a sidewall of the stuffing box and into corresponding holes within the cap of the walking beam compressor. Once the piston rod seal assembly is assembled and secured to the compressor and around the piston rod, a pneumatic grease gun or other injecting mechanism can be used to inject additional injectable fibrous sealant through a port and button head fitting within a sidewall of the stuffing box and into an interior portion of the stuffing box to fill in space around the cylindrical sealing element and to place the entire system under pressure. The system can be pressurized up to and including a pressure of 8,000 pounds to ensure a proper seal is formed. The system can be subsequently re-pressurized as needed to maintain the seal over time.
In use, the piston rod is connected to a walking beam of an oil well pump. Thus, the piston rod is configured for reciprocal movement in response to rocking of the walking beam as it acts to pump oil out of the ground. The reciprocating motion of the piston rod is effective to facilitate the compression of gas within the walking beam compressor having the piston rod seal assembly coupled to a top portion thereof. The piston rod is therefore moving in and out of a highly pressurized environment (within the walking beam compressor) and the piston rod seal assembly provides the transition between the compressor and the environment. The piston rod seal assembly will therefore provide a fluid and gas tight seal around the reciprocating piston rod between the walking beam compressor and the atmosphere.
A person skilled in the art will appreciate that, while the exemplary method described in connection with the particular embodiments disclosed herein, the method can vary significantly depending on the particular configuration of the piston rod seal assembly as well as the walking beam compressor.
One skilled in the art will appreciate further features and advantages of the invention based on the above-described embodiments. Accordingly, the invention is not to be limited by what has been particularly shown and described, except as indicated by the appended claims. All publications and references cited herein are expressly incorporated herein by reference in their entirety.