Sensorless pressure change detection for servo gun
First Claim
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1. A method for detecting pressure changes at servo gun tips of a robotic welding system having a servo gun with a movable tip and an opposed fixed tip configured to weld a part comprising the steps of:
- storing benchmark values for a spring constant, a pressure estimator, an efficiency and an inertia/friction during noload operation;
operating the servo gun to apply a first calibrated force at the gun tips and measuring a resulting first deflection value at the gun tips using a non-contact optical sensor;
operating the servo gun to apply a second calibrated force at the gun tips and measuring a resulting second deflection value at the gun tips using the optical sensor;
using the measured first and second deflection values and the pressure estimator to calculate current values for the spring constant, a first gun tip pressure, a second gun tip pressure, the efficiency and the inertia/friction during noload operation;
comparing each of the current values with a corresponding one of the benchmark values; and
generating an error indication for any of the current values that differs from the corresponding benchmark value by a predetermined amount.
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Abstract
A method and an apparatus detects pressure changes at servo gun tips of a robotic welding system having a servo gun with a movable tip and an opposed fixed tip configured to weld a part. The method and apparatus observe a tip deflection value and convert the value to a current pressure value using a pressure estimator. The current pressure value is compared to a benchmark pressure value to detect any difference.
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Citations
20 Claims
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1. A method for detecting pressure changes at servo gun tips of a robotic welding system having a servo gun with a movable tip and an opposed fixed tip configured to weld a part comprising the steps of:
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storing benchmark values for a spring constant, a pressure estimator, an efficiency and an inertia/friction during noload operation; operating the servo gun to apply a first calibrated force at the gun tips and measuring a resulting first deflection value at the gun tips using a non-contact optical sensor; operating the servo gun to apply a second calibrated force at the gun tips and measuring a resulting second deflection value at the gun tips using the optical sensor; using the measured first and second deflection values and the pressure estimator to calculate current values for the spring constant, a first gun tip pressure, a second gun tip pressure, the efficiency and the inertia/friction during noload operation; comparing each of the current values with a corresponding one of the benchmark values; and generating an error indication for any of the current values that differs from the corresponding benchmark value by a predetermined amount.
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2. The method according to claim 1 including selecting a standard force value;
- calculating a motor torque command based upon the standard force value and a motor torque constant for a motor to actuate the servo gun with a corresponding calibrated torque value;
determining a calculated force value from the calibrated torque value and a pressure calibration table.
- calculating a motor torque command based upon the standard force value and a motor torque constant for a motor to actuate the servo gun with a corresponding calibrated torque value;
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3. The method according to claim 2 including forming the pressure estimator by plotting two points of calibrated pressure values and corresponding measured deflection values of the gun tips, drawing a line between the points, and converting the line to an equation for determining a new calibrated force value from a new measured deflection value.
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4. The method according to claim 1 including if the spring constant current value is different from the spring constant benchmark value generating an error indication.
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5. The method according to claim 1 including if the first pressure current value is different from the first pressure benchmark value generating an error indication.
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6. The method according to claim 5 including only generating the error indication if the difference is greater than ten percent.
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7. The method according to claim 1 including if the second pressure current value is different from the second pressure benchmark value generating an error indication.
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8. The method according to claim 7 including only generating the error indication if the difference is greater than ten percent.
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9. The method according to claim 1 including if the efficiency current value is different from the efficiency benchmark value generating an error indication.
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10. The method according to claim 9 including only generating the error indication if the difference is less than or greater than a predetermined range of a ratio of the efficiency current value to the efficiency benchmark value.
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11. The method according to claim 10 wherein the range is 65% to 135%.
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12. The method according to claim 1 including only generating the error indication if the Inertia/friction current value is different from the inertia/friction benchmark value.
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13. The method according to claim 12 including only generating the error indication if the difference is greater than thirty percent.
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14. The method according to claim 1 including performing tip wear measurements on the gun tips and only performing the steps if the tip wear measurements meet predetermined wear schedule conditions.
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15. The method according to claim 1 including generating the error indication from a computer controlling the servo gun in response to any of the current values differing from a corresponding one of the benchmark values.
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16. An apparatus for detecting pressure changes in a robotic welding system comprising:
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a servo gun with a movable tip opposed by a fixed tip; a motor coupled to the movable tip for moving the movable tip toward and away from the fixed tip; a non-contact optical sensor configured to detect tip deflection values; a computer connected to the motor for actuating the motor to move the movable tip; and a pressure test computer program executed by the computer causing the motor to move the movable tip to apply a first pressure at the fixed tip, the motor then move the movable tip to apply a second pressure at the fixed tip, the computer to store the tip deflection values measured by the optical sensor for the first and second pressures, the computer to calculate and store values for a spring constant, a pressure force estimator, efficiency and inertia/friction during noload operation from the stored deflection values, and if the pressure test is a first pressure test, designate the stored values as benchmark values.
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17. The apparatus according to claim 16 wherein if the pressure test is not the first pressure test, designate the stored values as current values.
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18. The apparatus according to claim 17 wherein the computer executes the pressure test computer program to generate an error indication in response to any of the current values differing from a corresponding one of the benchmark values.
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19. A method for detecting pressure changes at servo gun tips of a robotic welding system having a servo gun with a movable tip and an opposed fixed tip configured to weld a part comprising the steps of:
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closing the movable tip against the fixed tip to apply a pressure at the tips; measuring, using a non-contact optical sensor, a deflection value of the fixed tip from a reference point corresponding to zero pressure at the tips; converting the deflection value to a calibrated pressure value using a pressure estimator; comparing the calibrated pressure value to a benchmark pressure value; and generating an error indication if a difference between the compared values exceeds a predetermined amount.
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20. The method according to claim 19 including generating the pressure estimator by plotting two points of calibrated pressure values and corresponding measured deflection values of the tips, drawing a line between the points, and converting the line to an equation for determining a new calibrated force value from a new measured deflection value.
Specification