Resistance spot welder adaptive control

US 4,447,700 A
Filed: 06/07/1982
Issued: 05/08/1984
Est. Priority Date: 06/07/1982
Status: Expired due to Term

First Claim

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1. A method of controlling a resistance spot welding process practiced on a welding machine which applies an electrode mechanical load to the workpieces and has a primary circuit and a secondary circuit that supplies power to the electrodes, comprising the steps of:

diagnosing the condition of said workpieces and machine before welding by measuring certain variables and determining that these variables are within predefined limits;

applying power pulses to weld said workpieces, measuring workpiece thermal expansion and expansion rate after every welding pulse and comparing respectively to a known target maximium expansion and to preset expansion rate limits, and dynamically adjusting the welding power as a function of workpiece thermal expansion and rate of expansion in order to control the formation of a weld nugget; and

supplying additional power pulses and dynamically adjusting the welding power after every power pulse to control the cooling rate and temper the welded workpiece.

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Abstract

The adaptive controller for a resistance spot welder is implemented with a microcomputer and peripherals to handle the monitoring of several process variable inputs and control the welding machine in real time. Before welding power is applied, electrode load, workpiece thickness and dynamic resistance are measured and must fall within predefined limits in order to continue. The workpiece, if necessary, is conditioned to correct fit-up and surface contamination problems by applying power pulses to lower its resistance. The welding power in each half cycle is dynamically adjusted as a function of workpiece thermal expansion and its first derivative to control formation of the weld nugget, and to control the cooling rate and temper the workpiece. During welding the power limits are adjusted in real time to compensate for electrode flattening and shunt effects. The quality of each weld is diagnosed and machine diagnostics are performed.

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17 Claims

1. A method of controlling a resistance spot welding process practiced on a welding machine which applies an electrode mechanical load to the workpieces and has a primary circuit and a secondary circuit that supplies power to the electrodes, comprising the steps of:
- diagnosing the condition of said workpieces and machine before welding by measuring certain variables and determining that these variables are within predefined limits;
  
  applying power pulses to weld said workpieces, measuring workpiece thermal expansion and expansion rate after every welding pulse and comparing respectively to a known target maximium expansion and to preset expansion rate limits, and dynamically adjusting the welding power as a function of workpiece thermal expansion and rate of expansion in order to control the formation of a weld nugget; and
  
  supplying additional power pulses and dynamically adjusting the welding power after every power pulse to control the cooling rate and temper the welded workpiece.
- View Dependent Claims (2, 3, 4, 5, 6, 13)
- - 2. The method of claim 1 wherein said welding power is measured during every welding power pulse and increased or decreased to bring said expansion rate and power within limits and compensate for flattened electrodes and current shunting.
  - 3. The method of claim 2 wherein the diagnosing step comprises measuring the combined thickness of said workpieces and computing said maximum expansion, and power pulses are applied to form the weld nugget until said maximum expansion is exceeded and said expansion rate is less than a predetermined value, and thereafter during the cooling stage until said thermal expansion is lower than a predefined value.
  - 4. The method of claim 1 wherein electrode displacement, electrode load, electrode voltage and electrode current are sensed each half cycle, a count of power pulses is made, and dynamic resistance, welding power, workpiece thermal expansion, and rate of expansion are computed each half cycle.
  - 5. The method of claim 1 wherein secondary circuit electromagnetic interference is sensed, and said load, voltage, and current are sensed at the interference zero.
  - 6. The method of claim 1 including the step of conditioning said workpieces before welding by applying one or more power pulses to bring one variable, initially out-of-limits, within said predefined limits.
  - 13. The method of claim 1 and the steps of computing target expansion values from the combined thickness of said workpieces, measuring workpiece thermal expansion and, in the case of negative expansion indicating there was a fit-up problem, remeasuring the combined thickness of said workpieces in order to recompute target expansion values.

7. The combination of a multivariable adaptive control and quality assurance system with a resistance spot welding machine which applies an electrode mechanical load to the workpieces and has a primary circuit with power devices to control the current and a secondary circuit that supplies power pulses to the electrodes, comprising:
- a plurality of sensors on said machine which measure selected machine and workpiece parameters;
  
  a microcomputer system and means for interfacing the signals generated by said sensors with said microcomputer system, and for interfacing commands generated by said microcomputer system with said welding machine;
  
  said microcomputer system and interfaces comprising means for diagnosing the condition of said machine and workpieces before welding by determining that certain of said parameters and welding variables derived from said measured parameters are within limits to realize an acceptable weld, and when not aborting the welding process; and
  
  means for producing power device firing signals to generate power pulses, and for dynamically adjusting the welding power in each half cycle of weld current as a function of workpiece thermal expansion and rate of expansion to control the formation of a weld nugget and to control the cooling rate of the welded workpiece.
- View Dependent Claims (8, 9, 10)
- - 8. The combination of claim 7 wherein said sensors include an electromagnetic interference sensor whereby other sensors can be sampled at the interference zero.
  - 9. The combination of claim 7 including a hardware arithmetic interface to augment the computational capability of said microcomputer system.
  - 10. The combination of claim 7 wherein said means for interfacing with the welding machine has power control circuitry which generates said power device firing signals in each half cycle of weld current and is comprised of a look-up table in which a function of τ
    - , a time equal to half the current pulse width, is expressed as a function of I_RMS², where I is the weld current, and a timer which produces said firing signals at a time after the primary circuit voltage zero which depends on τ
      
      .

11. A method of controlling a resistance spot welding process practiced on a welding machine which applies an electrode mechanical load to the workpieces and has a secondary circuit that supplies power to the electrodes, comprising the steps of:
- diagnosing the condition of said workpieces and machine before welding by measuring certain variables including the combined thickness of said workpieces and dynamic resistance, and electrode load;
  
  conditioning said workpieces when the measured dynamic resistance is above-limits but not higher than a predetermined value in order to correct surface contamination and mechanical fit-up problems, by applying one or more power pulses to reduce said dynamic resistance;
  
  aborting the process when at least one variable is not within predefined limits; and
  
  applying power pulses to weld said workpieces after it has been determined that all of said variables are within range such that an acceptable weld is achievable.
- View Dependent Claims (12, 14)
- - 12. The method of claim 11 wherein secondary circuit electromagnetic interference is sensed, and welding parameters from which at least some of said variables are derived are sensed at the electromagnetic interference zero.
  - 14. The method of claim 11 and displaying a diagnostic indication to the operator giving the reason for aborting the process and corrective action where possible.

15. A multivariable adaptive controller to be used with a resistance spot welding machine which applies on electrode mechanical load to the workpieces and has a primary circuit with power devices to control the current and a secondary circuit that supplies power pulses to the electrodes, comprising:
- a plurality of sensors on said machine which measure selected workpiece and machine parameters;
  
  first means for diagnosing the condition of said workpieces and machine before welding by checking the thickness of said workpieces and electrode load and by producing a low power diagnostic pulse and checking power device misfire and workpiece dynamic resistance and determining that these variables are or are not within predefined limits to realize an acceptable weld, and aborting the welding process in the latter case;
  
  second means for conditioning said workpieces before welding by generating one or more power pulses to correct surface contamination and mechanical fit-up problems and bring dynamic resistance, initially out-of-limits, within said predefined limits; and
  
  third means for producing power pulses, measuring welding power and workpiece variables during every power pulse, and dynamically adjusting said welding power after every power pulse to control the formation of a weld nugget.
- View Dependent Claims (16, 17)
- - 16. The controller of claim 15 wherein said workpiece variables are thermal expansion and rate of expansion.
  - 17. The controller of claim 16 wherein said first means includes means for displaying to the operator the reason for aborting the welding process.

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Current Assignee
General Electric Company
Original Assignee
General Electric Company
Inventors
Cohen, Robert K.
Primary Examiner(s)
Shaw, C. C.

Application Number

US06/386,153
Time in Patent Office

701 Days
Field of Search

219/110, 219/109, 219/117.1
US Class Current

219/117.1
CPC Class Codes

B23K 11/252 using digital means

Resistance spot welder adaptive control

First Claim

1 Assignment

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Abstract

92 Citations

17 Claims

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Resistance spot welder adaptive control

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

92 Citations

17 Claims

Specification

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