Welding monitoring and control system

US 4,024,371 A
Filed: 12/18/1974
Issued: 05/17/1977
Est. Priority Date: 12/18/1974
Status: Expired due to Term

First Claim

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1. In combination, a welding control system and a pulse type welder wherein pulsed energy is fed from a source of varying voltage to a welding load during a weld period, the control system including sensing means for sensing the voltage and current flowing in the load, the improvement comprising means for generating a standard impedance characteristic from a first set of voltage and current values sensed by the sensing means and storing said characteristic, generating means for generating a subsequent impedance characteristic of the load from subsequently sensed voltage and current values sensed by the sensing means, means for comparing said subsequent and said standard impedance characteristic and altering the pulses of energy to the load in response to said comparison, interface means connected to the sensing means and the generating means for feeding the sensed voltage and current signals to the generating means, a signal generation circuit which generates a signal indicative of the start of the weld period, and a peak detector means connected to the sensing means for sensing a peak characteristic of at least one of the voltage and current and controlling the feeding of the voltage and current signals to the generating means, said peak detector means including a timing circuit and a clock circuit for generating a plurality of pulses which are counted by said timing circuit to time a period from the start of the weld period to an assumed peak, said timing circuit including a presettable counter circuit that is connected to said clock circuit and adapted to be preset to a predetermined number in response to said start of weld period signal, said clock circuit altering said counter to time out said counter upon counting a preselected number of pulses from said clock circuit.

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Abstract

A monitoring and control system for use in conjunction with a pulsation type welder which utilizes a computer to calculate the impedance characteristics of a weld and compare these characteristics to a preselected set of characteristics to determine if a quality weld has been made. The system then controls the heat and cool time to increase or decrease the temperature of the weld and thus control the size of the weld nugget. The monitoring control system is utilized in conjunction with a standard pulsation welding control system, which standard system provides a series of heat impulses each followed by a cool interval, this cycle being repeated for a preselected number of cycles. The monitoring and control system senses the voltage and current in the welding load and feeds this data to a computer which, in turn, calculates the impedance of the weld. This calculation is then compared to a predetermined set of standards which are evolved as a result of processing a preselected number of previous welds, and corrections are made to assure the weld quality. If the weld is not developing sufficiently, the number of cycles in the cool portion of the impulse, and thus, the cool time, is reduced until the weld meets the set standards. On the other hand, if the weld exceeds the standard, the number of heat cycles, and thus the heat time, is reduced.

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18 Claims

1. In combination, a welding control system and a pulse type welder wherein pulsed energy is fed from a source of varying voltage to a welding load during a weld period, the control system including sensing means for sensing the voltage and current flowing in the load, the improvement comprising means for generating a standard impedance characteristic from a first set of voltage and current values sensed by the sensing means and storing said characteristic, generating means for generating a subsequent impedance characteristic of the load from subsequently sensed voltage and current values sensed by the sensing means, means for comparing said subsequent and said standard impedance characteristic and altering the pulses of energy to the load in response to said comparison, interface means connected to the sensing means and the generating means for feeding the sensed voltage and current signals to the generating means, a signal generation circuit which generates a signal indicative of the start of the weld period, and a peak detector means connected to the sensing means for sensing a peak characteristic of at least one of the voltage and current and controlling the feeding of the voltage and current signals to the generating means, said peak detector means including a timing circuit and a clock circuit for generating a plurality of pulses which are counted by said timing circuit to time a period from the start of the weld period to an assumed peak, said timing circuit including a presettable counter circuit that is connected to said clock circuit and adapted to be preset to a predetermined number in response to said start of weld period signal, said clock circuit altering said counter to time out said counter upon counting a preselected number of pulses from said clock circuit.
- View Dependent Claims (2)
- - 2. The improvement of claim 1 wherein said presettable counter has a maximum count to which it can be incremented, said predetermined number of counts to which said presettable counter is preset, when added to the number of counts to be counted during said timing period, will be equal to said maximum number of counts.

3. In combination, a welding control system and a pulse welder having a welding cycle including heat portions and cool portions, the pulse welder including at least one welding head, a source of welding pulses, a standard control circuit connected between the source and the welding head for controlling the application of alternate of the heat and cool portions to a welding load by controlling the number of welding pulses fed to the load during the heat portion and the duration of the cool portion, the standard control circuit including means for generating a series of clock pulses for controlling the duration of the heat and cool portions of the welding cycle of the load by counting a preselected number of clock pulses in the heat and cool portions of the cycle, and means connected to the standard control circuit for altering the duration of the heat and/or cool portions of the cycle counted by the standard control, the improvement comprising start means for sensing the start of a heat portion and generating a start signal indicative thereof, sensing means for sensing a first set of voltage and current characteristics flowing in the load during a heat portion, means for generating a standard impedance characteristic from said sensed first set of voltage and current characteristics flowing in the load and storing said standard characteristic, an interface circuit connected to the current and voltage sensing means and said impedance characteristic generating means for feeding the voltage and current signals to said impedance characteristic generating means, said sensing means sensing a second set of voltage and current characteristics flowing in the load during another heat portion, said generating means generating a second impedance characteristic from said second set for each welding pulse of said another heat portion, means for comparing said second impedance characteristics of each welding pulse with the standard impedance characteristic and generating an altering signal in response to the generated standard characteristics, said altering signal generating means connected to the standard control for altering the heat and/or cool portions of the welding cycle to maintain said second impedance characteristic within limits of said standard characteristic, and peak detector means for detecting a peak characteristic of at least one of said voltage and current and controlling the time of generation of said sensed voltage characteristic and sensed current characteristic in response to the detection of said peak characteristic, said peak detector means including a timing circuit and a clock circuit for generating a plurality of pulses which are counted by said timing circuit to time a period from the start of a heat portion to an assumed peak, said timing circuit including a presettable counter circuit that is connected to said clock circuit and adapted to be preset to a predetermined number in response to said start signal, said clock circuit altering said counter to time out said counter upon counting a preselected number of pulses from said clock circuit.
- View Dependent Claims (4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
- - 4. The improvement of claim 3 wherein said presettable counter has a maximum count to which it can be incremented, said predetermined number of counts to which said presettable counter is preset, when added to the number of counts to be counted during said timing period, will be equal to said maximum number of counts.
  - 5. The improvement of claim 4 further including an end of weld generation circuit for generating an end of weld signal indicative of the end of the heat portion, said welding system providing welding pulses between said start signal and said end of weld signal.
  - 6. The improvement of claim 5 wherein said end of weld signal is fed to said altering signal generating means to terminate the altering of said heat and/or cool portions.
  - 7. The improvement of claim 6 wherein said end of weld generation circuit is fed said start signal, the termination of said start signal generating said end of weld signal.
  - 8. The improvement of claim 7 wherein said start signal is a transition of a signal level from one level to another, said signal remaining at said another level during the heat portion of the weld and forming a weld signal.
  - 9. The improvement of claim 8 wherein said end of weld signal generation circuit includes a trigger circuit responsive to a transitional edge of said weld signal, the transition from said another level to said one level generating said end of weld signal.
  - 10. The improvement of claim 3 wherein said voltage and current characteristics flowing in the load are analog signals, the system further including an analog-to-digital converter circuit for converting said analog signal to digital signals.
  - 11. The improvement of claim 10 wherein said analog-to-digital converter circuit includes first and second operational amplifiers connected to the welding load, said operational amplifiers generating an output signal in response to the magnitude of current flowing in the welding load.
  - 12. The improvement of claim 11 wherein said analog-to-digital converter circuit is common to both said operational amplifiers, one of said operational amplifiers sensing the current flowing in the load and the other of said operational amplifiers sensing the voltage flowing in the load.
  - 13. The improvement of claim 12 wherein said converter circuit includes a plurality of inputs, said converter circuit being adapted to be switched to convert any one of said inputs at the input circuits to said digital signals, said digital signals having a plurality of bits.
  - 14. The improvement of claim 13 wherein said current sensing operational amplifier is connected to one of said input circuits and said voltage sensing operational amplifier is connected to another of said circuits, said converter circuit being adapted to be switched between said current input and said voltage input circuits.
  - 15. The improvement of claim 14 wherein the output of said converter circuit is connected to a plurality of shift registers, the number of shift registers corresponding to the number of bits generated in said digital signal.
  - 16. The improvement of claim 15 wherein said shift registers and said output of the converter circuit are common to both said current sensing and said voltage sensing operational amplifiers, said converter circuit being switched to provide one of said current and voltage signals and then switch to provide the other of said current and voltage signals.
  - 17. The improvement of claim 16 wherein said welding system includes a computer for providing said impedance characteristic, said converter circuit and said shift register providing said computer with digital current and voltage signals to provide means for generating said impedance characteristic.
  - 18. The improvement of claim 17 wherein said data is stored in said shift register upon sensing said current and voltage data, said computer generating a transmit data signal for outputting data from said shift registers to said computer.

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Current Assignee
Kelsey-Hayes Co. (Zeppelin - Stiftung der Stadt Friedrichshafen)
Original Assignee
Kelsey-Hayes Co. (Zeppelin - Stiftung der Stadt Friedrichshafen)
Inventors
Drake, Charles J.
Primary Examiner(s)
Truhe, J. V.
Assistant Examiner(s)
Shaw, Clifford C.

Application Number

US05/534,342
Time in Patent Office

881 Days
Field of Search

219/110, 219/108, 219/111, 235/151.1, 235/151.31, 324/65 R
US Class Current

219/110
CPC Class Codes

B23K 11/252 using digital means

Welding monitoring and control system

First Claim

2 Assignments

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Abstract

Citations

18 Claims

Specification

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Welding monitoring and control system

First Claim

2 Assignments

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0 Petitions

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Accused Products

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Abstract

Citations

18 Claims

Specification

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Solutions

Use Cases

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