The description herein makes reference to the accompanying drawings wherein like reference numerals refer to like parts throughout the several views, and wherein:
The present invention provides a method for conducting diagnostic tests of spray equipment 12 located within a painting station 10, as shown in
In order to allow control of the spray equipment 12 from outside the painting station 10, a human machine interface 22 is provided outside of the painting station 10 and operatively connected to the spray equipment 12 to allow the operator 14 to control the spray equipment 12 and receive digital feedback data from sensors provided on the spray equipment 12 and associated test equipment. The digital feedback data provided by the sensors on the spray equipment 12 may include, but is not limited to, voltages of electrostatic spray equipment, rotational velocities of bell cups, and flow rates of paint and cleaning agents. Furthermore, the digital feedback data may be provided based on either direct or indirect measurements.
In order to provide a data set for comparison purposes, data is gathered empirically regarding the performance characteristics of interest by directly measuring the performance of the spray equipment 12 using known empirical methods. This is typically performed during commissioning of the spray equipment 12 or during later maintenance or recalibration, and the results of these measurements may be validated by comparing the empirically gathered data to performance specifications provided by the manufacturer of the spray equipment 12. While the empirical data is gathered, the digital feedback from the spray equipment 12 is recorded and correlated with the empirical measurements to create a baseline data set.
During the automated diagnostic tests, digital feedback data is gathered remotely by the operator 14 using the human machine interface 22, and the digital feedback data is compared to the baseline data set. If the values of the current test data and the baseline data set are within a predefined window the test is considered passed and the results are stored for further review. If the difference is outside the predefined window the test fails. This comparison is performed automatically by the human machine interface 22, eliminating the need to resort to written standards. The result of the comparison is a “pass or fail” indication that is presented to the operator 14 and simultaneously recorded by human machine interface 22. A graph may be displayed overlaying both sets of results and highlighting the deviation in a failed test, and this graph may also be stored for further review. Optionally, the spray equipment 12 may be disabled until the failure is corrected. Thus, entry of the operator 14 into the hazardous area 16 is minimized by empirically gathering valid test data to establish a baseline data set, utilizing a human machine interface 22 located outside of the hazardous area 16 to automatically gather test data, comparing the automatically gathered test data with the empirically gathered data in the previously acquired baseline data set, and providing a signal if the automatically gathered data differs from the empirically gathered data by a predetermined amount.
In many cases, by comparing the digitally gathered feedback data to benchmark data gathered using empirical methods, the operator 14 is not required to enter the hazardous area 16 at all. For example, the electrostatic performance and the rotational performance of the spray equipment 12 may be verified without entry into the hazardous area 16.
Alternatively, the human machine interface may be employed to conduct diagnostic tests wherein, test equipment or test media is introduced into the hazardous area 16 of the painting station 10 through the maintenance hatch 18. By way of example, this may be useful to validate paint delivery system performance and cleaning agent delivery system performance by way of a flow test, or to otherwise gather a volumetric sample. After the operator 14 instructs the human machine interface 22 to start the desired test, the spray equipment 12 automatically moves into position adjacent to the maintenance hatch 18. Once the spray equipment 12 has reached the desired position, the human machine interface 22 prompts the operator 14 to begin the lockout procedure. The user then operates the lockout device 20 to deactivate the spray equipment 22. After the human machine interface 22 confirms that the spray equipment 12 has been deactivated using the lockout device 20, the human machine interface 22 prompts the operator 14 to open the maintenance hatch 18. The operator 14 then opens the maintenance hatch and places the test equipment or the test media, as required, into the hazardous area 16 of the painting station 10 through the maintenance hatch 18. In the case of a flow test, a beaker or other measurement vessel may be placed into the hazardous area 16 of the painting station 10 through the maintenance hatch 18. After the test equipment or media is in place, the operator 14 may close the maintenance hatch 18 and operate the lockout device 20 to reactivate the spray equipment 12. The operator 14 then uses the human machine interface 22 to execute the desired test. Once the test is completed, the test equipment or test media may be retrieved from the painting station 10 through the maintenance hatch 18. If necessary, the operator 14 can be prompted by the human machine interface 22 to enter the results of the test, which may be stored in a database. The test may be repeated using other parameters as necessary. At the conclusion of the testing, the test results are compared to the baseline data set for comparison and analysis as previously described.
By another alternative, diagnostic tests may be performed using empirical methods in a manner that precludes having the operator 14 make multiple entries into the hazardous area 16, and which eliminates the need for the operator to be present in the hazardous area 16 while the spray equipment 12 is activated. By way of example, color change performance and paint spray patterns may be validated in this manner.
In order to initialize the test, the operator 14 instructs the human machine interface 22 to start the test. Upon starting the test, the spray equipment 12 moves to a safe position. Once the spray equipment 12 is in a safe position, the human machine interface 22 prompts the operator 14 to use the lockout device 20 to deactivate the spray equipment. The human machine interface 22 monitors the lockout device 20 for compliance, and prompts the operator 14 when the spray equipment 12 is deactivated and it is thus safe to enter the hazardous area 16. To prepare the spray equipment 12 for the diagnostic test, the operator 14 enters the hazardous area 16 and places the test media 24 in the hazardous area 16 within the painting station 10. After exiting the hazardous area 16, the operator 14 activates the spray equipment 12 using the lockout device 20, and the human machine interface 22 may proceed with the test. After the spray equipment 12 completes the test, the operator 14 retrieves the test media 24 from the hazardous area 16, operating the lockout device 20 as necessary. The human machine interface 22 then prompts the operator 14 to enter the results of the test, which may be stored in a database by the human machine interface 22.
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiments, but to the contrary, it is intended to cover various modifications or equivalent arrangements included within the spirit and scope of the appended claims. The scope is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures as is permitted under the law.
This application claims the benefit of U.S. Provisional Application No. 60/813,242, filed Jun. 13, 2006, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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60813242 | Jun 2006 | US |