The present disclosure relates to a device that measures strain in a component and more particularly to a device that measures diametral strain in a cylindrical component and the measurements are used to calculate the load and stress within the cylindrical component.
In many industries, it is important to measure the variable dynamic or static axial loads that may be imposed on a cylindrical member or shaft. This is especially true in the nuclear power industry where motor operated valves are used extensively. Monitoring of the various operating parameters of the valves is required by the nuclear power regulating agencies. Motor operated valves are comprised generally of an electric motor driven actuator that is connected to a valve stem and a valve yoke that partially surrounds the valve stem.
It has been observed that one of the ways to monitor certain dynamic forces and events that occur during the operation of a valve is by measurement of the valve stem axial loads using either axial or diametral extensometers.
It is known that one can calculate the axial load or stress in a valve stem, or any other similar member, by measuring changes in the diameter of the valve stem. The ratio of the diametral change to axial elongation, referred to as Poisson's ratio, is known and available for most materials. Therefore, by measuring the diametral changes in the valve stem using a device such as a diametral extensometer, axial strains and valve stem axial loads can be easily calculated and determined. However, the sensitivity and stability of current extensometer designs are often lacking in order to achieve accurate readings.
The entire contents of U.S. provisional patent application 61/335,149, to which priority is claimed above, is hereby incorporated herein by reference.
The present disclosure is directed to a strain measuring device that senses diametral changes in a cylindrical component and measures such diametral change using strain sensing elements arranged on a frame of the strain measuring device. The strain sensing elements may measure tensile and compressive strain developed in the frame as a result of the frame flexing via diametral growth of the component.
Briefly described, the strain measuring device comprises a rigid frame. Generally, the frame has an outer surface and an inner surface spaced from the outer surface in a radial direction. The frame also has a planar first side surface generally parallel to and spaced from a planar second side surface. The rigid frame may be an arcuate frame or a “C” shaped frame. The strain measuring device may further comprise a first contact assembly arranged at, or near, an end of the frame and a second contact assembly arranged on an opposite end of the frame. A passage extends through the frame along an axis that is substantially parallel with a longitudinal axis and the passage arranged on the frame between the first contact assembly and the second contact assembly. An inner web is defined between the passage and the inner surface of the frame and an outer web is defined between and the outer surface of the frame and the passage. The strain measuring device further comprises at least a first strain sensing element contacting either the inner web or the outer web. In some embodiments, the strain measuring device may comprise a second strain sensing element contacting the web not contacted by the first strain sensing element. The strain sensing elements may be mounted to the webs of the frame to measure substantially pure tensile and compressive strains developed in the frame as a result of the diametral growth of the component.
In another embodiment, the strain measuring device may comprise a body defining a first mounting portion and a second mounting portion spaced apart and interconnected by a central body portion. A first clamp head may be mounted to the first mounting portion, for engagement with a shaft. A second clamp head may be mounted to the second mounting portion, for engagement with a shaft, and spaced from the first clamp head. The first clamp head and said second clamp head are aligned along and spaced apart along a common centerline that does not intersect said central body portion. A passage extends through said central body portion and is proximate either the first clamp head or the second clamp head.
Yet another embodiment of the disclosure is a method of measuring a load on a cylindrical component. The method may comprise the steps of:
(a) mounting at least two strain sensing elements to the cylindrical component;
(b) applying a load to the cylindrical component;
(c) simultaneously sensing a substantially pure tensile strain at a first of the strain sensing elements and a substantially pure compressive strain at a second of the strain sensing elements in response to a diametral change in the cylindrical component as effected by the load; and
(d) converting the sensed strains to a value equal to the load applied to the shaft.
These and other aspects of the present invention will become apparent to those skilled in the art after a reading of the following description of the preferred embodiments when considered in conjunction with the drawings. It should be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention as claimed.
According to common practice, the various features of the drawings discussed below are not necessarily drawn to scale. Dimensions of various features and elements in the drawings may be expanded or reduced to illustrate more clearly the embodiments of the disclosure.
For clarity of discussion, the following three directional definitions and coordinate system are commonly used when discussing a strain measuring device as discussed herein and are used throughout this application and applicable to all embodiments disclosed herein. A cylindrical coordinate system 1 has a longitudinal axis “α,” radial axis “β,” and a circumferential axis “φ.” “Longitudinal” refers to a longitudinal axis “α” oriented in a direction parallel to a longitudinal axis of a shaft 12. “Radial” refers to a direction orthogonal to the longitudinal direction and to a radial axis “β” oriented in a direction extending outward from the longitudinal axis. “Circumferential” refers to an angular axis “φ” or direction that orients the radial axis “β” relative to either of the two reference axes 3, 4 perpendicular to the longitudinal axis α. Collectively, the three directional axes α, β, φ establish the cylindrical coordinate system 1. For purposes of the present disclosure, the longitudinal direction α generally refers to a direction along the shaft 12 and the lateral direction β generally refers to a direction extending from the center of the shaft 12 (See for example the “directional vane” adjacent
Referring now in more detail to the drawing figures, wherein like reference numerals indicate like parts throughout the several views,
With reference to
The passage 30 may be generally rectangular in shape or cross-section, wherein the cross-section is the cross-section in planar view, i.e. when viewed in the plane of the first side surface 26 or the second side surface 28. In other embodiments, the passage 30 may be square, circular, oval, polygonal, or any other cross-section that provides an appropriate strain field in the passage 30. An appropriate strain field is understood to be a strain field that is sensitive to diametral changes in the component and can be measured with a specified accuracy by the strain sensing elements 46, 48. The passage 30 is bounded on the inside and outside by an inner web 50 and a outer web 52, respectively, and by first and second side walls 53, 55. The inner web 50 may lie in a first plane and the outer web 52 may lie in a second plane and the first and second planes may be generally parallel to one another and generally perpendicular to a common centerline (i.e. centerline 62). The passage 30 may have a passage width 32 that is the distance between first and second side walls 53, 55. The passage 30 has a passage height that is the distance between interior surfaces of the webs 50, 52. The inner web 50 has a web thickness 38 that is the distance from an inner web contact surface 54 to a ridge 43 and the ridge extends a distance 38 from the inner web contact surface 54. The ridge 43 may function to make the strain in the inner web 50 more constant over the web 50. The outer web 52 also has a web thickness, which is the distance from a outer web contact surface 56 to the ridge 43′. The ridge 43′ may function to make the strain in the outer web 52 more constant over the web 52. The distance between the inner web contact surface 54 and the outer web contact surface 56 is given by 34. Each of the corners of the generally rectangular passage 30 may have a fillet 41. As illustrated, each fillet 41 has the same fillet radius 42. However, it is not required that each fillet 41 have the same fillet radius 42 and in some embodiments, each fillet radius 42 may be different. A fillet edge is spaced a distance 36, for example, from the inner web contact surface 54. The fillet 41 in part functions to reduce a local stress that may develop at a stress concentration that generally occurs at a corner. The second side wall 55 is spaced a distance 44 from a centerline 62 of the first support assembly interface 60. Strain sensing elements 46, 48 are arranged on the inner web contact surface 54 and outer web contact surface 56, respectively. The inner web contact surface 54 and outer web contact surface 56 and the strain sensing elements 46, 48 may be sized so the strain sensing elements 46, 48 cover a majority of their respective web contact surface 54, 46 to at least obtain a more accurate measurement of the local strain in their respective webs 50, 52. The strain sensing elements 46, 48 may measure the strain associated with the flexing of the body 20. The strain measuring elements 46, 48 will be subjected to bending and placed in substantially pure tension and substantially pure compression, respectively. Thus, another general concept of the strain measuring device is placement of the strain sensing elements 46, 48 on the body 20 so one of the strain sensing elements 46 may measure a substantially pure tensile strain and one of the strain sensing elements 48 may measure a substantially pure compressive strain. In some embodiments, the magnitude of tensile strain measured by the strain sensing element 46 may be approximately the same as the magnitude of compressive strain measured by the strain sensing element 48 during component 12 testing.
Strain sensing elements 46, 48 may have measuring axes that are generally tangent with the circumferential direction cp. When the strain measuring device 10 is fabricated, the first strain sensing element 46 may be installed and configured to be compressively loaded and the second strain sensing element 48 may be installed and configured to be loaded in tension. One reason for such an installation is so when the strain measuring device 10 is installed, the strain measuring device 10 can be adjusted so the first strain sensing element 46 and the second strain sensing element 48 produce a reading of “zero” strain prior to any component testing or monitoring.
Several of the dimensions or parameters of the passage 30 may be adjusted to improve the sensitivity and stability of the strain measuring device 10. Adjusting the passage width 32, the distance 36 from the inner web contact surface to the upper fillet radii 40 (as well as the corresponding distance from the outer web contact surface to the lower fillet radii), the fillet radius 42, and the distance 44 from the centerline 62 of the first support assembly interface 60 to the second side wall 55 of the passage 30. The skilled artisan will understand that adjusting the size of the passage may mean adjusting the sensitivity of the strain sensing elements 46, 48 by increasing the deformation in the webs 50, 52. These parameters 32, 40, 42, 44 are but a few of the possible parameters or dimensions that may be adjusted. Other viable parameters that may be adjusted will be any parameter that significantly affects the local strain in the webs 50, 52. Thus, another general concept of the strain measuring device 10 is the adjustment of several dimensions of the passage 30 to increase the strain in the webs 50, 52 to improve the ability of the strain sensing elements 46, 48 to measure said strain. The dimensions of the passage 30 may be adjusted to produce a large value of strain in the webs 50, 52 while remaining below the elastic limit of the material. The elastic limit of the material will be understood by the skilled artisan to be the maximum stress or force per unit area that can arise within the material before the onset of permanent deformation. When stresses or strains up to the elastic limit are removed, the material resumes its original size and shape.
As an example, and not meant to limit the scope of the present disclosure in any way, the following table, Table 1, provides example ranges of several of the passage dimensions.
As another example, the ranges for dimensions listed in Table 1 above may have the following discrete values: dimension 32 may be 0.130 inches; dimension 36 may be 0.180 inches; dimension 38 may be 0.028 inches; dimension 40 may be 0.049 inches; dimension 42 may be 0.031 inches; and dimension 44 may be 0.240 inches.
Support assemblies 70, 80 are mounted at opposite sides of the body 20 and secure the strain measuring element 10 to a component (See, for example, shaft 12 of
The first support assembly 70 may be comprised of a support element 72. The support element 72 may include a “vee” type head element 73. The “vee” type head element 72 may be easier to align with the component 12, especially if the component 12 is cylindrical. The “vee” of the head element 73 may be oriented so a vertex of the “vee” is parallel with the longitudinal axis α and thus parallel to the component longitudinal axis. In some embodiments, a ball bearing may be included to improve device 10 alignment with respect to the component 12. The second support assembly 80 generally comprises a support element 82, a threaded spindle 84, a set screw 86, a plate 88, a retaining pin 92 and a ball bearing 90. The support element 82 may include a “vee” type head element 83 (See
The strain measuring device 10 can be manufactured from any suitable material including steel and steel alloy. Preferably, the device is manufactured from titanium. The material for the strain measuring device 10 should be selected with environment and duty cycle in mind to ensure sufficient mechanical and thermal properties to operate properly as well as respond properly to the load condition. The strain measuring device 10 can be fabricated using any acceptable fabrication method such as machining, casting, or forging. The device 10 may be fabricated from a plurality of different materials if desired.
Generally, the component or shaft 12, such as, for example a valve stem, experiences tensile and compressive loads while moving, for example, a valve head through a range of motion. Other examples of tensile and compressive loads on a shaft are evident to one skilled in the art. When the tensile or compressive load is applied to the shaft 12, the diameter of the shaft will either decrease or increase, respectively. The strain measuring device 10 measures the change in diameter of the shaft 12. From this measurement, an algorithm can determine the load being applied to the shaft 12 and how the load is being applied, i.e. the cyclic nature of the load as well as the magnitude of the load. As the diameter either increases or decreases, the body 20 of the strain measuring device 10 will flex either outward or inward, respectively. The term “flex” used throughout this document will be understood by the skilled artisan to mean a deformation of the body 20, with the body ends moving towards each other or away from each other. Strain sensing elements 46, 48, such as strain gauges, are attached to the strain measuring device 10 and measure the changes in the body 10, and are then related to the changes in the diameter of the shaft 12, and the load being applied to the shaft 12 can be determined.
In use, the strain measuring device 10 is first mounted to the shaft 12 that is to be monitored or evaluated. The strain measuring device 10 is secured to the shaft 12 by rotating the threaded spindle 84 of the second support assembly 80 to firmly contact the shaft 12. The strain measuring device 10 is properly aligned relative to the shaft 12 when the plane that is occupied by the two support elements 70, 80 is approximately perpendicular to the longitudinal axis a of the shaft 12. This is necessary because the arrangement of the strain sensing elements 46, 48 will be measuring tensile and compressive strains in the body 20 induced by the diametral changes of the shaft 14 during shaft loading. The second support element 82 should be advanced toward the component 12 so the head elements 73, 83 of the support assemblies 70, 80 clamp onto the shaft 12. The second support element 82 should be further advanced to increase the strain in the body 20 until the strain sensing elements 46, 48 are reading approximately zero strain. The strain measuring device 10 is now “zeroed.” When the shaft 12 is loaded along the longitudinal axis α, the diameter of the shaft 12 will either increase or decrease. For example, if the load applied along the longitudinal axis α is compressive, the shaft diameter will increase as a result of the compression. Thus, when the diameter of the shaft 12 increases, a flexing force will be applied to the body 20 at the support elements 70, 80 and cause the body 20 to flex or bend. Because of the design of the passage 30 and the action of the head elements 73, 83, upon mounting to shaft 12, a tensile strain may be developed in the inner web 50 and a compressive strain may be developed in the outer web 52. With the tensile and compressive strain measurements from strain elements 46, 48, the load applied along the longitudinal axis a can be determined and the mechanical integrity of the shaft 12 evaluated.
Certain modifications and improvements will occur to those skilled in the art upon a reading of the foregoing description. It should be understood that all such modifications and improvements have been deleted herein for the sake of conciseness and readability but are properly within the scope of the following claims.
This application claims the benefit of the filing date of U.S. Provisional Application No. 61/335,149, filed Dec. 31, 2009.
Number | Date | Country | |
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61335149 | Dec 2009 | US |