This invention relates to sensors for detecting surface wear in one or both contacting surfaces of a machine, where at least one of the contacting surfaces comprises a conductive material.
Relative motion between contacting components in a machine (e.g., high performance machines or engines) can result in excessive wear of one or both components. For example, components subjected to high frequency and low frequency vibrations may result in excessive wear of component attachments or mating surfaces. The component wear, if left undetected, can cause component and machine malfunctions. For example, spring clips in combustion turbine engine experience surface wear from contact with other components due to operational vibrations and dynamic forces.
In some applications, component wear can be controlled to acceptable levels by using lubricants, by employing materials with high resistance to wear and/or by design features that limit motion and contact and resulting component wear. However, there are many situations where relative motion cannot be eliminated, such as in brake linings, meshing gears, contacting sliders and slip fits; wear is unavoidable in such applications.
Knowledge of the wear condition of critical components can be used to avoid forced outages due to unexpected component failures. Such knowledge also enables the machine to be shut down for repair of the worn components at a convenient scheduled time, rather than continuing operation until a component is worn beyond repair or an emergency shut down is required. Significant costs can be saved by both avoiding forced outages and by ensuring the worn parts can be repaired instead of scrapped when a scheduled outage is performed.
The extent of wear and the suitability of the component for continued service can be determined by visual and/or dimensional inspection. In some applications, wear indicators are embedded within or proximate one or more of the contacting surfaces. For example, in the context of brake linings, wear limit notches or “squealers” generate an audible warning when a predetermined amount of lining wear has occurred.
However, there are many applications where periodic inspection is not feasible due to such factors as, for example, time and labor expenses, cost of inspection and operational disruptions due to inspection down time. In addition, visual and audible warnings are not always feasible monitoring solutions, as is the case when monitoring internal components of a gas turbine engine. Thus, there is a need for a system that can monitor component wear while the component is in an operational state.
Wear sensors mounted in one or both of the wearing components can advantageously provide real-time monitoring of component wear during machine operation. These sensors measure the amount of wear that occurs in regions prone to wear and notify an operator when a preselected amount of wear has occurred. The sensors improve machine reliability and enable more accurate maintenance planning. Such monitoring also improves safety and reduces operating and maintenance costs by indicating a maintenance requirement before any component damage occurs. Real time wear monitoring also avoids unscheduled outages.
A conductive wear sensor is described in commonly-owned U.S. Pat. No. 7,270,890, entitled, Wear Monitoring System with Embedded Conductors. The patent describes a sensor comprising a closed circuit conductive trace that is transformed to an open circuit condition when a counterface wears through the conductive trace. While this sensor has many applications, frequently both members of a wear couple (i.e., two components in contact along the wear surface) are electrically conductive metals. An open circuit cannot be detected in such an electrically conductive component.
The invention is explained in the following description in view of the drawings that show:
Before describing in detail the particular methods and apparatuses related to an open circuit wear sensor for use with a conductive counterface in accordance with various aspects of the present invention, it should be observed that the present invention, in its various embodiments, resides primarily in a novel and non-obvious combination of hardware and method steps. Accordingly, the hardware and method steps have been represented by conventional elements in the drawings, showing only those specific details that are pertinent to the present invention so as not to obscure the disclosure with details that will be readily apparent to those skilled in the art having the benefit of the description herein.
The following described embodiments are not intended to define limits of the structures or methods of the invention but to provide only exemplary constructions. The embodiments are permissive rather than mandatory and illustrative rather than exhaustive.
According to the present invention, an open circuit wear sensor, comprising for example two proximate wear sensor conductors configured in an open-circuit arrangement, is formed in a dielectric substrate or a conductive substrate. In the latter application, the wear sensor conductors are insulated from the conductive substrate. In either case, a dielectric layer (a wear surface or wear coating) is formed over the wear sensor conductors and when the wear surface is worn by a conductive wear counterface, the conductors are exposed and the counterface interconnects (bridges) or shorts the conductors. This action completes a circuit and provides an indication (a wear indication) that the wear surface has been breached.
Generally, the wear surface (also referred to as a wear resistant coating or simply a wear coating) is defined as the outermost material layer that contacts the wear counterface. A material of the wear surface may be conductive or insulative. As applied to the present invention, in the former situation, the wear sensor conductors are insulated from the conductive material of the wear surface. In any case, the wear sensor conductors of the present invention are disposed below the wear surface, within the wear surface, within the substrate or within a material layer between the substrate and the wear surface.
A wear indicator connected to the conductors is energized only when the dielectric material is breached and the wear sensor conductors are shorted by the wear counterface. The wear indicator is not energized when the conductors are open.
The wear sensor conductors may be deposited on or within any coated or uncoated substrate material, on or within any material layer, or within the wear layer material. For example, the wear sensor conductors may be disposed with a trench formed in the material. Although a material of the substrate and the wear layer may be conductive or insulative as described above, a material of the wear counterface must be electrically conductive (or comprise an electrically conductive region) to short the conductors and activate the wear indicator.
In another embodiment, the conductors 12 and 14 are disposed within the wear surface 16 between an upper wear surface 16A and a lower wear surface 16B. See
As illustrated in
A wear sensor 38 comprising two wear sensor conductors 40 and 42, see
A dielectric layer 46 (which can serve as the wear surface layer or wear coating) is formed over the wear sensor conductors 40 and 42 and completely or partially over exposed regions of the upper surface 32A. See
As shown in
Although end regions 40C and 42C of the conductors 40 and 42 are illustrated in
When the dielectric wear surface layer 46 is worn through, see
According to another embodiment, the conductors 68 and 69 are not required, as a wireless transceiver is connected to the regions 40B and 42B for transmitting a wireless signal when the wear conductors 40 and 42 are shorted by the wear counterface. The signal is received by an external receiver for activating a wear indicator.
A material of the substrate 30 may comprise a dielectric or a metal, as described above, or another material such as a ceramic or ceramic matrix composite. An appropriate deposition process for forming the wear sensor conductors on these substrate materials may be accordingly selected, as is known in the art.
In an application where a conductive layer 104 (see
In an alternative embodiment the wear sensor conductors are disposed within a trench formed in the dielectric layer 138.
The wear sensor conductors of the present invention may be deposited on the substrate or within the wear-resistant layer (e.g., a metal, ceramic, or cerment coating) or another material layer using a thin film deposition process such as plasma spraying, electron beam physical vapor deposition, chemical vapor deposition, pulsed laser deposition, mini-plasma, cold spray, direct-write, mini high velocity oxy-fuel, or solution plasma spraying, for example.
In certain applications of the present invention the substrate is fixed while the wear counterface moves while in contact with the substrate. Since the wear counterface closes a conductive path between the two wear sensor conductors disposed within the stationary substrate, it is unnecessary to construct an electrical circuit (with attendant conductors) within the moving wear counterface and connect that circuit to external electrical devices (e.g., a power source and a wear indicator). This invention thus avoids the use of elements typically employed to electrically connect to a moving or rotating element, (e.g., brushes and slip rings). All installation and maintenance actions related to the wear sensor conductors are performed on the stationary substrate.
The various sensor conductors described herein may be formed as follows.
In another embodiment, a trench or groove 160 is formed in a wear substrate 162 for receiving wear sensor conductors 170 and 172. See
If the wear substrate 162 comprises conductive material, a trench bottom region 160A and trench sidewall regions 160B and 160C comprise an electrically insulating material 166 that insulates the wear sensor conductors 170 and 172 from each other and from the conductive substrate 162.
In
In both the
In the embodiments of
In yet another embodiment, the wear sensors 170 and 172 are formed in separate trenches 190 and 192 in the substrate 162, as illustrated in
In still another embodiment, the wear sensors 170 and 172 are formed in separate trenches 193 and 194 in the wear coating layer 180, as illustrated in
In yet another embodiment, the wear sensor comprises two pairs of wear sensor conductors, each conductor pair formed at a different depth below a surface of the coating or a surface of the substrate. See
When a material layer 200 above a first or upper-most conductor pair 202 and 204 is breached, the counterface shorts or interconnects the first conductor pair 202 and 204 and closes an electrical circuit to actuate a first wear indicator, indicating that the material layer 200 has worn to a depth d1. A top surface 208A of a material layer 208 is now exposed. When the wear counterface wears the first conductor pair 202 and 204 and wears a portion of the material layer 208 above a second conductor pair 222 and 224 a different electrical path is completed when the wear counterface interconnects the conductors 222 and 224. This action energizes a second wear indicator indicating the material layer 208 has been worn to a depth d2. Additional conductors can be disposed at different depths to provide a graded indication of the wear depth. Different maintenance actions can be performed depending on the depth of material wear.
The teachings of the present invention can also be employed where two contacting or proximate components vibrate, the vibrations bringing the two components into contact and wearing one or both of the components.
The teachings of the present invention can also be employed in a system where two components are in a close proximal relationship during normal operation. Operational anomalies cause the two components to contact, which can lead to operational difficulties. The conductive sensors of the present invention are formed in a first one of the components and when contacted by a second component, the conductive sensors are shorted and an alarm activated. In this application it may advisable to form the conductive sensors in a trench as illustrated in
In yet another embodiment, it may be desirable to orient the wear conductor sensors relative to a direction of motion of the wear counterface to preclude any smearing of the material of the conductor sensors. Such smearing may bridge the gap between the conductors, shorting the conductors and obviating the shorting function of the wear counterface.
Thickness dimensions are set forth herein for certain of the material layers. However, it is recognized that these dimensions are not critical to the functionality of the present invention. The thickness of the wear sensor conductors (e.g., conductors 40 and 42) is also not critical to the functionality of the present invention, except that a duration of the short (as determined by a thickness of the conductors before the conductors are completely destroyed by wearing) must be sufficiently long to provide an indication of the short, thereby warning that the wear surface has worn away.
The various material layers described above according to the various embodiments may comprise a thermal barrier layer, a substrate layer, a dielectric layer, a wear coating layer (a wear resistive coating or a wear surface), a conductive layer, a ceramic layer or any other layers known in the art. A material of each of these layers may be selected based on the application, proximate materials, and expected wear affects of the wear counterface. Also, material layers below the wear surface are selected based on the application and the proximate layer materials.
As used herein the terms “open” and “short” when applied to electrical circuits do not require a respective infinite resistance and a zero resistance. The terms are intended to suggest a very high resistance (e.g., greater than about several mega-ohms) through which little current flows or a very low resistance (e.g., less than about 100 ohms) through which a considerable current flows. The actual values of resistance and current in any particular application are dependent on the materials comprising the conductors, the substrate and the wear counterface and on the configuration of the electrical circuit. Also, the term “interconnect” as used herein requires a connection between two conductors through which current can flow. An interconnect does not necessarily require a short circuit.
One application for the present invention includes a gas turbine having rotating turbine blades that may wear a surrounding shroud. Mounting the wear sensor of the present invention in material layers comprising the shroud provides a wear warning when the shroud has been worn by the blades to a depth of the wear sensor.
While various embodiments of the present invention have been shown and described herein, it will be obvious that such embodiments are provided by way of example only. Numerous variations, changes and substitutions may be made without departing from the invention herein. Accordingly, it is intended that the invention be limited only by the spirit and scope of the appended claims.