Patent Number: 050088416
Section: claims

1. A non-invasive monitoring system for a valve of the type including a housing and a movable element mounted in the housing for movement between an open position and a closed position and intermediate positions between the open and closed positions comprising: (a) first means for both detecting acoustic energy produced by the valve during a monitoring interval and generating data representative of the detected acoustic energy;  (b) second means for both detecting signals indicative of the position of the movable element during the monitoring interval and generating data representative of the detected signals; and  (c) third means coupled to the first and second means for simultaneously receiving the data generated by the first and second means and providing data from which a condition of the valve can be determined by a user.  (a) computer means programmed to identify significant data corresponding to impacts of internal elements of the valve resulting from movement of the movable element and corresponding to the position of the movable element at times that substantially coincide with the internal impacts; and  (b) display means coupled to the computer means and responsive to the significant data to provide a display of the significant data.  (a) analog to digital converter means for converting the analog voltage signals generated by the first and second means to digital voltage signals;  (b) digital signal processing means coupled to the analog to digital converter means and programmed to locate digital voltage signals corresponding to impacts of internal elements of the valve resulting from movement of the movable element and corresponding to the position of the movable element at times that substantially coincide with the internal impacts; and  (c) display means operatively coupled to the digital signal processing means and responsive to the located digital voltage signals to provide a display of the located digital voltage signals.  (a) detecting acoustic energy produced by the valve during a monitoring interval and generating data representative of the detected acoustic energy;  (b) detecting signals indicative of the position of the movable element during the monitoring interval and generating data representative of the detected signals; and  (c) processing the data generated in steps (a) and (b) to place the data generated in steps (a) and (b) in a form for detecting various conditions within the valve.  (i) identifying significant data corresponding to impacts of internal elements of the valve resulting from movement of the movable element and corresponding to the position of the movable element at times that substantially coincide with the internal impacts; and  (ii) displaying said significant data.  (a) detecting acoustic energy produced by the valve during a monitoring interval and generating data representative of the detected acoustic energy;  (b) detecting signals indicative of the position of the movable element during the monitoring internal and generating data representative of the detected signals; and  (c) recording the data generated in steps (a) and (b) for subsequent analysis.  (d) processing the data recorded in step (c) to place the recorded data in a form for analysis.  (e) analyzing the data processed in step (d) to detect various conditions within the valve.  (a) mounting an accelerometer and a Hall effect generator on the exterior of the housing; and  (b) processing the output signals of the accelerometer and the Hall effect generator to place the same in a form for detecting various conditions within the valve.  (i) locating output signals of the accelerometer corresponding to internal impacts resulting from movement of the movable element;  (ii) locating output signals of the Hall effect generator corresponding to the position of the movable element at times that substantially coincide with the internal impacts; and  (iii) displaying the located output signals of the accelerometer and the Hall effect generator for analysis.  (a) mounting a piezoelectric accelerometer and a Hall effect generator on the exterior of the housing;  (b) effecting movement of the movable element; and  (c) during step (b) simultaneously recording the output signals of the accelerometer and the output signals of the Hall effect generator.  (d) processing the recorded output signals of the accelerometer and the recorded output signals of the Hall effect generator to place the same in a form for analysis.  (i) identifying significant output signals of the accelerometer corresponding to impacts of internal elements of the valve resulting from movement of the movable element and identifying significant output signals of the Hall effect generator corresponding to the position of the movable element at times that substantially coincide with the internal impacts; and  (ii) displaying the significant output signals of the accelerometer and Hall effect generator for analysis.  (e) analyzing the data processed in step (d) to detect various conditions within the valve. 2. A non-invasive monitoring system according to claim 1 wherein the third means comprises recording means for recording the data generated by the first and second means. 3. A non-invasive monitoring system according to claim 1 wherein the third means comprises data processing means for processing the data generated by the first and second means to place the data generated by the first and second means in a form for analysis. 4. A non-invasive monitoring system according to claim 3 wherein the data processing means comprises: 5. A non-invasive monitoring system according to claim 1 wherein the first means comprises an accelerometer. 6. A non-invasive monitoring system according the claim 5 wherein the accelerometer comprises a piezoelectric crystal accelerometer. 7. A non-invasive monitoring system according to claim 1 wherein the second means comprises magnetic field generating means mounted on the movable element for movement therewith to provide a varying magnetic field as the position of the movable element changes, and magnetic field strength sensing means for detecting the strength of the magnetic field provided by the magnetic field generating means and for generating signals proportional to the strength of the magnetic field detected thereby. 8. A non-invasive monitoring system according to claim 7 wherein said magnetic field generating means comprises a permanent magnet and said magnetic field strength sensing means comprises a Hall effect generator. 9. A non-invasive monitoring system according the claim 1 wherein the first means comprises a piezoelectric crystal accelerometer and the second means comprises a permanent magnet mounted on the movable element for movement therewith and a Hall effect generator. 10. A non-invasive monitoring system according to claim 9 wherein the piezoelectric crystal accelerometer and the Hall effect generator are disposed within a single container, the container being mounted on the exterior of the valve housing. 11. A non-invasive monitoring system according to claim 1 wherein the first means generates data in the form of analog voltage signals representative of the detected acoustic energy; the second means generates data in the form of analog voltage signals representative of the detected signals; and wherein the third means comprises data processing means for processing the data generated by the first and second means to place the data generated by the first and second means in a form for analysis; the data processing means comprising: 12. A non-invasive method of monitoring a valve of the type having a housing and an internal element mounted in the housing for movement between open and closed positions and intermediate positions between the open and closed positions comprising the steps of: 13. A non-invasive method of monitoring a valve according to claim 12 wherein step (c) comprises: 14. A non-invasive method of monitoring a valve of the type having a housing and an internal element mounted in the housing for movement between open and closed positions and intermediate positions between the open and closed positions comprising the steps of: 15. A non-invasive method of monitoring a valve according to claim 14 further comprising the step of: 16. A non-invasive method of monitoring a valve according to claim 15 further comprising the step of: 17. A non-invasive method of monitoring a valve of the type having a housing and an interval element mounted in the housing for movement between open and closed positions and intermediate positions between the open and closed positions, the moveable element having a permanent magnet located thereon for movement therewith, comprising the steps of: 18. A non-invasive method of monitoring a valve according to claim 17 wherein step (b) comprises: 19. A non-invasive method of monitoring a valve of the type having a housing and an internal element mounted in the housing for movement between open and closed positions and intermediate positions between the open and closed positions, the movable element having a permanent magnet located thereon for movement therewith, comprising the steps of: 20. A non-invasive method of monitoring a valve according to claim 19 further comprising the step of: 21. A non-invasive method of monitoring a valve according to claim 20 wherein step (d) comprises: 22. A non-invasive method of monitoring a valve according to claim 21 further comprising the step of: