초록 ▼

A method of measuring weld thermal response as a function of time during the production of a resistance weld includes monitoring a first parameter responsive to a change in an electrode mechanical load on workpieces welded together with respect to the electrode mechanical load applied prior to appli

A method of measuring weld thermal response as a function of time during the production of a resistance weld includes monitoring a first parameter responsive to a change in an electrode mechanical load on workpieces welded together with respect to the electrode mechanical load applied prior to application of the heat, monitoring a second parameter responsive to a change in position of linkage applying the electrode load with respect to linkage position prior to application of the heat, and processing a composite of the first parameter and the second parameter to produce a derived measurement representative of the thermal response of the weld. Electrode force and electrode current are also monitored via sensors and measurements calibrated to provide more accurate information during the welding process.

대표청구항 ▼

1. A method of measuring weld thermal response as a function of time during the production of a weld on a resistance welding machine, comprising: positioning workpieces between electrodes of the resistance welding machine and applying an electrode mechanical load to the workpieces using the electrod

1. A method of measuring weld thermal response as a function of time during the production of a weld on a resistance welding machine, comprising: positioning workpieces between electrodes of the resistance welding machine and applying an electrode mechanical load to the workpieces using the electrodes;applying voltage across the workpieces and generating heat which raises the temperature of the workpieces; monitoring a first parameter responsive to a change in the electrode mechanical load with respect to the electrode mechanical load applied prior to application of the heat;monitoring a second parameter responsive to a change in position of linkage applying the electrode load with respect to linkage position prior to application of the heat;processing a composite of the first parameter and the second parameter to produce a derived measurement representative of the thermal response of the weld;wherein the derived measurement is adjusted thermal force (“ATF”) applied by the electrodes to the workpieces, the adjusted thermal force being calculated by measuring an initial electrode force (“EF1”) with a first sensor and initial linkage position (“LP1”) with a second sensor prior to application of heat. 2. The method of claim 1, further comprising determining a spring constant (“K”) of the linkage, and calculating ATF as ATF=(EF2−EF1)+K·(LP2−LP1). 3. The method of claim 2, wherein the electrode force is measured with a force transducer. 4. The method of claim 2, wherein the adjusted thermal force (ATF) is converted to an expansion measurement by dividing ATF by the spring constant (K). 5. The method of claim 2, further comprising monitoring electrode force using a composite measurement which is a function of information from two sensors wherein one sensor monitors force applied to the linkage applying the electrode force and the other sensor monitors a change in electrode force during the weld, the method including automatically calibrating the sensors to increase accuracy of measurement of instantaneous electrode force as a function of time. 6. The method of claim 5, further comprising monitoring electrode current using two current sensors wherein a first current sensor measures current during a short duration at the start of the weld and the second current sensor measures current for the balance of the weld, the first current sensor providing a calibrated accurate current reading upon initiation of current for a limited duration of time after the first current is applied to the electrodes and the second current sensor providing an output signal that is a linear function of electrode current over an extended duration of time. 7. The method of claim 1, further comprising measuring current flowing through the electrodes by measuring an initially applied current flowing through the electrodes using an initial calibrated current sensor, and a sensor which measures a linear output indicative of current, dividing an initial calibrated current sensor measurement by the linear output to determine a calibration factor, continuing to monitor the current with the initial calibrated current sensor, and processing the linear output with the calibration factor to calculate the current flowing through the electrodes during the weld. 8. The method of claim 7, further comprising determining whether the calculated current falls within a predetermined tolerance range of targeted values. 9. A method of monitoring electrode current as a function of time during the production of a weld on a resistance welding machine wherein electrodes apply an electrode mechanical load to workpieces and a circuit applies voltage across the workpieces such that current flows through the workpieces and generates heat which raises the temperature of the workpieces, the method comprising: monitoring electrode current using two current sensors wherein a first current sensor measures current during a short duration at the start of the weld and the second current sensor measures current for the balance of the weld,the first current sensor providing a calibrated accurate current reading upon initiation of current for a limited duration of time after the first current is applied to the electrodes andthe second current sensor providing an output signal that is a linear function of electrode current over an extended duration of time. 10. The method of claim 9, wherein before transitioning to the second current sensor, a calibration factor is calculated on the basis of simultaneous measurements of the first and second current sensors and the calibration factor is applied to the output of the second current sensor. 11. A method of measuring current as a function of time during the production of a weld on a resistance welding machine wherein electrodes apply an electrode mechanical load to workpieces and a circuit applies voltage across the workpieces such that current flows through the workpieces and generates heat which raises the temperature of the workpieces, the method comprising: measuring current flowing through the electrodes by measuring an initially applied current flowing through the electrodes using an initial calibrated current sensor, and a sensor which measures a linear output indicative of current,dividing an initial calibrated current sensor measurement by the linear output to determine a calibration factor,continuing to monitor the current with the initial calibrated current sensor, andprocessing the linear output with the calibration factor to calculate the current flowing through the electrodes during the weld. 12. A method of measuring weld thermal response as a function of time during the production of a weld on a resistance welding machine wherein electrodes apply an electrode mechanical load to workpieces and a circuit applies voltage across the workpieces such that current flows through the workpieces and generates heat which raises the temperature of the workpieces, the method comprising: monitoring a first parameter responsive to a change in the electrode mechanical load with respect to the electrode mechanical load applied prior to application of the heat;monitoring a second parameter responsive to a change in position of linkage applying the electrode load with respect to linkage position prior to application of the heat;processing a composite of the first parameter and the second parameter to produce a derived measurement representative of the thermal response of the weld;measuring an initially applied current flowing through the electrodes using an initial calibrated current sensor and a sensor which measures a linear output indicative of current, dividing an initial calibrated current sensor measurement by the linear output to determine a calibration factor, continuing to monitor the current with the initial calibrated current sensor, and processing the linear output with the calibration factor to calculate the current flowing through the electrodes. 13. A method of measuring weld thermal response as a function of time during the production of a weld on a resistance welding machine, comprising: positioning workpieces between the electrodes of the resistance welding machine and applying an electrode mechanical load to workpieces using the electrodes;applying voltage across the workpieces and generating heat which raises the temperature of the workpieces;monitoring a first parameter responsive to a change in the electrode mechanical load with respect to the electrode mechanical load applied prior to application of the heat;monitoring a second parameter responsive to a change in position of linkage applying the electrode load with respect to linkage position prior to application of the heat;processing a composite of the first parameter and the second parameter to produce a derived measurement representative of the thermal response of the weld;monitoring of electrode force using a composite measurement which is a function of information from two sensors wherein one sensor monitors force applied to the linkage applying the electrode force and the other sensor monitors a change in electrode force during the weld, the method including automatically calibrating the sensors to increase accuracy of measurement of instantaneous electrode force as a function of time. 14. A method of measuring weld thermal response as a function of time during the production of a weld on a resistance welding machine wherein electrodes apply an electrode mechanical load to workpieces and a circuit applies voltage across the workpieces such that current flows through the workpieces and generates heat which raises the temperature of the workpieces, the method comprising: monitoring a first parameter responsive to a change in the electrode mechanical load with respect to the electrode mechanical load applied prior to application of the heat;monitoring a second parameter responsive to a change in position of linkage applying the electrode load with respect to linkage position prior to application of the heat;processing a composite of the first parameter and the second parameter to produce a derived measurement representative of the thermal response of the weld;monitoring electrode current using two current sensors wherein a first current sensor measures current during a short duration at the start of the weld and the second current sensor measures current for the balance of the weld, the first current sensor providing a calibrated accurate current reading upon initiation of current for a limited duration of time after the first current is applied to the electrodes and the second current sensor providing an output signal that is a linear function of electrode current over an extended duration of time. 15. The method of claim 14, wherein before transitioning to the second current sensor, a calibration factor is calculated on the basis of simultaneous measurements of the first and second current sensors, the method further comprising conditioning the output signal of the second current sensor by applying the calibration factor to the output signal of the second current sensor. 16. The method of claim 15, wherein: (a) the first current sensor comprises a Rogowski coil which outputs current measurements to a monitoring system which integrates the current measurement before or upon initiation of current to the electrodes, (b) calibration of the second current sensor comprises dividing a parameter representative of current measured by the first current sensor by conditioned signal output of the second current sensor, and/or (c) the second sensor calibration is performed when current increases sufficiently to provide a predetermined sensor output resolution but before integration offset error introduces measurement inaccuracy exceeding resolution of the second current sensor output. 17. The method of claim 15, wherein the conditioning of the output signal of the second current sensor comprises subtracting an offset from the second current sensor output. 18. The method of claim 14, wherein the second current sensor is a Hall effect sensor responsive to a magnetic field produced from the electrode current. 19. The method of claim 14, wherein the second current sensor is a primary current measuring device.