The disclosure is generally related to the field of fluid handling systems, and more particularly to an improved system for monitoring wear of pump linings.
Screw pumps are rotary, positive displacement pumps that use two or more screws to transfer high or low viscosity fluids or fluid mixtures along an axis. Generally, a three-screw pump is a positive rotary pump in which a central one of three screws is motor-driven, and the two further screws are idlers meshing with diametrically opposed portions of the driven central screw, the idlers acting as sealing elements that are rotated hydraulically by the fluid being pumped. The volumes or cavities between the intermeshing screws and a liner or casing transport a specific volume of fluid in an axial direction around threads of the screws. As the screws rotate the fluid volumes are transported from an inlet to an outlet of the pump. In some applications, these pumps are used to aid in the extraction of oil from on-shore and sub-sea wells.
Often the liquids pumped through these pumps include entrained solids, such as sand. The presence of sand and other solids can cause damage to the pump internals, most notably to the pump casing, where the solids can pass between the screws and the casing. Substantial wear of the pump casing can undesirably result in reduced discharge flow rates. Repair of pump casings can be expensive, and thus, many manufacturers line the pump casing with a self-repairing liner material. Such liners are typically made from material that is much softer than the casing and screws. Thus, damage due to entrained solids is borne by the liner and not the more expensive casing. Such liners may be “self-repairing,” in that over time, scratches and gouges caused by contact with entrained solids may be smoothed over, mitigating their impact on performance of the pump.
While such liners can improve pump lifecycle, periodic liner refurbishment is still required. A difficulty remains, however, in determining when liner replacement should occur. As noted, liner degradation may manifest itself in reduced output flow from the pump. Where multiple pumps serve a single outlet, however, it can be difficult to identify which pump may be the cause of reduced overall flow. Thus, it would be desirable to provide a system and method for continuously monitoring wear of pump casing liners so that repair can be performed in a timely manner.
Wear monitoring systems, in general, are known. For example, U.S. Pat. No. 6,945,098 to Olson discloses a wear detection system for use in determining wall thinning in hydrocyclone applications, U.S. Pat. No. 6,290,027 to Matsuzaki, U.S. Pat. No. 5,833,033 to Takanashi, and U.S. Pat. No. 4,274,511 to Moriya disclose systems for detecting wear of brake pads, and U.S. Pat. No. 3,102,759 to Stewart discloses a system for detecting wear of journal bearings. The problem with these systems is that they may not be as accurate as desired. This is because the systems employ wear sensors made of materials that have compositions and properties different from the compositions and properties of the components being monitored. Owing to such differences, the sensors may wear at a faster or slower rate than the monitored components. As will be appreciated, where sensor wear is not consistent with component wear, the accuracy of the monitoring system is adversely affected.
Thus, there remains a need for an improved wear monitoring system that can continuously monitor wear of pump casing liners so that repair can be effected in a timely manner. Such a system should overcome the deficiencies inherent in current systems, and should be highly accurate. It would also be desirable to provide a system and method for storing liner wear information so that wear trending can be accomplished.
This disclosed wear detector is designed to detect erosion wear in a screw pump. This device detects wear in the idler bores. The idler bores are designed to provide an oil film build up with the idler rotors according to journal bearing theory. As such, under normal operating conditions the idler rotors do not come in contact with the idler bores, but rather they ride on an oil film. The disclosed wear detector is design to erode away at the same rate as the Babbitt lined pump bores when heavy debris is present. Therefore it is important that the sensor be made from a material that erodes at the same rate as the Babbitt material of the pump lining. The disclosed design can also detect film type failure modes. Film failure is where the pump's conditions change and the idlers come into contact with the idler bores.
A system for monitoring wear of pump casing liners is disclosed. The system may include a wear sensor disposed in proximity to the pump casing liner so that the sensor wears at substantially the same rate as the lining. A signal representative of the sensor wear is provided to a control system which logs the wear information and uses that information to signal a user when one or more predetermined wear thresholds are exceeded.
A system is disclosed for monitoring pump lining wear. The system may comprise a wear detector having a housing portion and a circuit portion. The wear detector may be disposed in a casing of a pump, where the pump has a casing liner. The housing portion may include a nose portion that is made from substantially the same material as the casing liner. The nose portion can be positioned flush with an inner surface of the casing liner adjacent a screw of the pump. The circuit portion can be disposed in or on the nose portion. The circuit portion may have at least one circuit loop electrically coupled to a conductor, and the conductor may be coupled to a controller for providing one or more signals to the controller representative of a thickness of the casing liner.
A system is disclosed for monitoring pump lining wear. The system may comprise a wear detector comprising a housing portion and a circuit portion, the wear detector disposed in a casing of a pump, the pump having a casing liner. The housing portion may have a nose portion that is made from substantially the same material as the casing liner. The nose portion may be positioned flush with an inner surface of the casing liner adjacent a screw of the pump. The circuit portion may be disposed in or on the nose portion. The circuit portion may have at least one circuit loop electrically coupled to a conductor. The conductor may be coupled to a controller to enable the controller to determine a thickness of the casing liner.
The circuit portion may comprise a flexible circuit including a plurality of conductive traces that form first and second circuit loops. The first circuit loop may be coupled to first and second contact openings, the second circuit loop may be coupled to the second contact opening and a third contact opening, and the first and second circuit loops may share a common ground. The first circuit loop may be longer than the second circuit loop such that the first circuit loop extends closer to the nose portion of the housing portion than the second circuit loop. When the nose portion is worn away by a first predetermined amount the first circuit loop may be broken, resulting in an open circuit configured to be sensed the controller. When the nose portion is worn away by a second predetermined amount the second circuit loop may be broken, resulting in an open circuit configured to be sensed by the controller.
The controller may be configured to recognize the opening of the first and second circuit loops as corresponding to respective first and second predetermined thickness reductions in the casing liner. The controller may include a processor and a memory, and may be configured to execute instructions for recognizing signals received from the wear detector as representative of one or more wear conditions of the casing liner. The memory may store data representative of the one or more wear conditions of the pump liner associated with time stamp data.
A wear detector is disclosed for monitoring pump lining wear. The wear detector may comprise a housing portion and a circuit portion. The housing portion may have a nose portion positionable flush with an inner surface of a pump casing liner adjacent a screw of a pump. The circuit portion may be disposed in or on the nose portion and may have at least one circuit loop electrically coupled to a conductor. The conductor may be coupled to a controller for providing one or more signals to the controller representative of a thickness of the casing liner. The circuit portion may comprise a flexible circuit including a plurality of conductive traces that form first and second circuit loops. The first circuit loop may be coupled to first and second contact openings, the second circuit loop is coupled to the second contact opening and a third contact opening, and wherein the first and second circuit loops share a common ground. The first circuit loop may be longer than the second circuit loop such that the first circuit loop extends closer to the nose portion of the housing portion than the second circuit loop. When the nose portion is worn away by a first predetermined amount the first circuit loop may be broken, resulting in an open circuit configured to be sensed the controller, and when the nose portion is worn away by a second predetermined amount the second circuit loop may be broken, resulting in an open circuit configured to be sensed by the controller.
A method is disclosed for monitoring pump lining wear. The method comprises: at a controller, determining a thickness of a pump casing liner based on signals received from a conductor associated with a wear detector; wherein the wear detector having a nose portion positioned flush with an inner surface of the pump casing liner, the nose portion made from substantially the same material as the pump casing liner, the wear detector having a circuit portion with at least one circuit loop disposed adjacent the nose portion, the at least one circuit loop electrically coupled to the conductor. The at least one circuit loop may comprise first and second circuit loops, the first circuit loop being longer than the second circuit loop such that the first circuit loop extends closer to the nose portion than the second circuit loop. The method may further comprise, at the controller, sensing a first open circuit condition when the nose portion is worn away by a first predetermined amount that breaks the first circuit loop and results in a first open circuit. The method may also comprise at the controller, sensing a second open circuit condition when the nose portion is worn away by a second predetermined amount that breaks the second circuit loop and results in a second open circuit. The controller may correlate the opening of the first and second circuit loops as corresponding to respective first and second predetermined thickness reductions in the pump casing liner.
By way of example, a specific embodiment of the disclosed device will now be described, with reference to the accompanying drawings:
Referring now to the drawings,
One or more inner surfaces of the pump casing 16 may be lined with a material that is different from the casing material to protect the pump casing 16 from damage during operation.
During operation, when entrained solids pass between the screws 24, 26 and the liner 30, the screws and liner may become worn or damaged. To maintain desired performance, the screws and liner may be periodically replaced. Traditionally, the liner is replaced at the same time the screws are replaced, since direct inspection of the liner throughout the casing is difficult. Changing the liner, however, requires that the pump be taken out of service and shipped to a maintenance facility. The problem with such a procedure is that liner replacement is not always necessary. With the disclosed system, the user is provided with a constant indication of liner thickness, and thus, if the system indicates that the liner remains above a certain critical thickness when it is time for the screws to be replaced, then only screw replacement can be carried out. The benefit is that screw replacement can be performed in the field, whereas liner replacement must be performed in the shop. As will be appreciated, this can result in lower cost and impact on operations, resulting in lower overall life cycle cost for the pump.
Referring now to
As can be seen, the wear circuit 36 may have a first end 42 with a plurality of contact openings 44 for coupling to a plurality of conductors 46 (
As can be seen in
In one embodiment, the first and second housing halves 34A, B of the wear sensor 32 are made from the same material as the casing liner 30. Thus, in an exemplary embodiment the first and second halves 34A, B are made from Babbit metal of a similar composition as that of the casing liner 30. Because the housing is made from the same material as the casing liner 30, the nose portion 50 of the sensor will experience wear at substantially the same rate as the liner. As the nose portion 50 wears, so does the circuit 36 which is disposed in or on the nose portion 50. As a result, wear of the wear circuit is directly proportional to wear of the liner 30.
Referring back to
The system may be configured to recognize the “opening” of each circuit 37A, B as corresponding to particular predetermined thickness reductions in the casing liner 30. In this way, the in situ thickness of the casing liner 30 can be continuously monitored, and the pump 10 can be taken off line and refurbished when the liner thickness reaches a critical value.
The display 64 of
As will be appreciated, in addition to this local display 64, a further remote display of data can also be provided. Further, an e-mail, fax or SMS text message can be sent to a predetermined address when one or more circuit loop breaks are sensed.
Based on the foregoing information, it will be readily understood by those persons skilled in the art that the present invention is susceptible of broad utility and application. Many embodiments and adaptations of the present invention other than those specifically described herein, as well as many variations, modifications, and equivalent arrangements, will be apparent from or reasonably suggested by the present invention and the foregoing descriptions thereof, without departing from the substance or scope of the present invention. Accordingly, while the present invention has been described herein in detail in relation to its preferred embodiment, it is to be understood that this disclosure is only illustrative and exemplary of the present invention and is made merely for the purpose of providing a full and enabling disclosure of the invention. The foregoing disclosure is not intended to be construed to limit the present invention or otherwise exclude any such other embodiments, adaptations, variations, modifications or equivalent arrangements; the present invention being limited only by the claims appended hereto and the equivalents thereof. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for the purpose of limitation.
This is a non-provisional of pending U.S. Provisional Patent Application Ser. No. 61/472,984, filed Apr. 7, 2011, the entirety of which application is incorporated by reference herein.
Number | Date | Country | |
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61472984 | Apr 2011 | US |