KR19990000244A - Current control device and method of spot welding machine using dynamic resistance value - Google Patents

Abstract

The present invention relates to a spot welding machine configured to be controlled by an ignition angle driven by the thyristors, the current provided to the electrode through the transformer, the current measuring unit connected to one end of the electrode to measure the welding current between the electrodes; A voltage measuring unit connected to one end of the electrode and measuring a welding voltage between the electrodes; Storage means for storing possible model dynamic resistance values of the nugget; A control for detecting a copper resistance value using a welding current and a voltage, calculating a next control current value using the copper resistance value and a model copper resistance value, and controlling an ignition angle of the thyristors in response to the control current value. Means.

That is, the present invention stores the model dynamic resistance values for obtaining a good welding quality in the storage means, and changes the current value corresponding to the difference between the dynamic resistance values during welding and the model dynamic resistance value, thereby making it possible to obtain a good nugget. There is an effect that can be obtained.

Description

Current control device and method of spot welding machine using dynamic resistance value

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spot welder, and more particularly, to an apparatus and method for controlling a current in a spot welder using a copper resistance value for controlling current to ensure weld quality.

Spot welding melt-bonds the contact parts of the base material by Joule heat using contact and compression resistance generated between the base materials by supplying a large current (8,000 ~ 30,000A) while pressing two or more thin sheets by air pressure between the electrodes. It is a welding method to obtain a simple and clean joint.

The three basic elements of such spot welding are pressurization, energization time, and energization. Therefore, the spot welding control device must sequentially perform operations such as pressurized cylinder operation, initial pressurization, energization, holding, and cylinder depressurization for the welding start request.

Weld quality in spot welding is indicated by weld marks remaining on the surface, weld size, strength, internal defects, and cracking of the metal surface as the welding base material. Double weld marks and flaring of the plate are externally exposed visual quality, weld strength and internal defects are items that are directly related to the quality of the actual welded structure. Weld quality generally refers to weld strength rather than externally revealed quality, and the evaluation method is judged by shear strength or sheet, that is, the size of a melt called a nugget formed between welded structures. This is because there is a proportional relationship between the size of the nugget and the shear strength. In general, since it is impossible to measure the cutting strength by cutting each part of the vehicle body in the field, the welding quality is judged by the size of the nugget generated after welding.

On the other hand, continuous welding leads to wear of the electrode tips and coating components on the surface of the plate, resulting in an increase in the cross-sectional area of the tip. The amount of heat required is reduced, and consequently the size of the nugget is reduced.

In other words, decreasing the size of the nugget means a decrease in strength by that amount, resulting in poor welding quality. Therefore, in order to maintain the original intended nugget size, appropriate compensation should be taken as the tip cross-sectional area increases. In general, the conventional method uses a function of an auto stepper that presets a welding RBI and raises or lowers a certain amount of current when the RBI is reached. Can't. Therefore, more reliable welding quality compensation measures are required.

SUMMARY OF THE INVENTION The present invention has been made in response to this demand, and an object of the present invention is to provide a current control device for a spot welder using the same copper resistance value that can ensure welding quality.

Another object of the present invention is to provide a current control method of a spot welder using the same copper resistance value that can ensure the welding quality.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the dynamic resistance characteristic in several welding area | regions for implementing this invention,

2 is a schematic block diagram showing an apparatus for controlling current of a spot welder using a copper resistance value according to the present invention;

* Description of the symbols for the main parts of the drawings *

2-1, 2-2: electrode 5: current detector

6: voltage detection unit 7: control device

8: rom

In order to achieve the above object, the present invention provides a point welder configured to control a current provided to an electrode through a transformer by an ignition angle driven by a thyristor, the current being connected to one electrode and measuring a welding current between the electrodes. A measuring unit; A voltage measuring unit connected to one end of the electrode and measuring a welding voltage between the electrodes; Storage means for storing possible model dynamic resistance values of the nugget; A control means for detecting the copper resistance value using the welding current and the voltage, calculating the next control current value using the copper resistance value and the model copper resistance value, and controlling the ignition angle of the thyristor in response to the control current value. Equipped.

The present invention also relates to a method of current control of a spot welder having information on the possible model dynamic resistance values of the nugget, wherein the welding current and voltage value are sensed every cycle or half cycle, and the dynamic resistance is calculated from these two values. Making a step; Calculating a difference between the two values by comparing the copper resistance value with the model value of the copper resistance; Calculating a current value to be compensated by multiplying the calculated difference value by a predetermined constant; Setting the control current value by adding the calculated compensation current value to the model current value based on the dynamic resistance model value; Providing a welding current corresponding to the control current value.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

First, looking at the basic technical idea to achieve the present invention.

According to the present invention, the model dynamic resistance value (welding voltage applied to the electrode is applied to the electrode every half cycle) by using the optimum condition pre-stored in the storage means, that is, the model value, regardless of various environmental changes during welding. It is to change the welding current and voltage value so as to follow.

In other words, many studies have shown that copper resistance well describes the thermal and physical phenomena of the formation and growth of the melted portion according to the flow of current during the welding process, and has a good correlation with the size of the melted portion.

Fig. 1 shows the change in dynamic resistance in various welding regions, in which the hatched region is a weldable region in which good welding quality, i.e., nugget is obtained.

In the present invention, the welding current and the voltage value are sensed every cycle or every half cycle, and the dynamic resistance is calculated from these two values. Then, this value is compared with the model value R _O 1 -R _O 5 of the copper resistance previously stored in the storage means to obtain the difference XR between the two values. This value (XR) is multiplied by a constant (K) to find the current value XI to be compensated for. The current value of the next half cycle is obtained by adding the compensation current value XI to the model current value to obtain the control current value.

As such, the model controls the dynamic resistance curve as much as possible with the lowest error, and as a result, it does not match the model dynamic resistance curve, but a similar dynamic resistance pattern can be obtained. It can be.

The equations associated with the above description are summarized as follows.

[Equation 1]

Where V _S is the welding voltage value

I _S is the welding current measured during half cycle

R _S is the calculated dynamic resistance

XR is the difference in dynamic resistance

R _O is the model dynamic resistance

K is a constant value

XI is the current compensation value

I _N is the next control current value

I _M is the model current value.

Hereinafter, an embodiment for carrying out the present invention described above will be described in detail.

2 is a schematic diagram of a spot welder for carrying out the present invention.

As shown, the current provided to the electrodes 2-1 and 2-2 through the transformer T1 is configured to be controlled by the signal i _gate applied to the gates of the thyristors SCR1 and SCR2. At this time, the current measuring unit 5 and the voltage measuring unit 6 are configured at one end of the electrode 2-1 or 2-2, and the current measuring unit 5 and the voltage measuring unit 6 are the electrodes 2. The welding current and voltage between -1 and 2-2 are measured and applied to the control device 7.

Here, the control device 7 is composed of a microprocessor and the like, and is configured to adjust the ignition angles of the thyristors SCR1 and 2 in response to the set current amount input from the user. In addition, the control device 7 detects the dynamic resistance value R _S using the welding current and the voltage of the current measuring part 5 and the voltage measuring part 6, and the moving resistance value R _S and the ROM. After calculating the next control current value I _N using the information in the (RH) or the lap (RAM) (8), the ignition angle of the thyristors SCR1, 2 corresponding to the control current value I _N. It is configured to control. Here, the model dynamic resistance values R _O 1-R _O 5 are stored in the ROM 8 as described above, and the control device 7 controls the next half cycle by using the above expression 1. The current value I _N can be easily calculated.

That is, the present invention stores the model dynamic resistance values that can obtain a good welding quality in the storage means, and changes the current value corresponding to the difference between the dynamic resistance values during welding and the model dynamic resistance value, thereby making it possible to obtain a good nugget. To get it.

As described above, the present invention has an effect that good welding quality can be obtained by controlling the dynamic resistance value during welding.

Claims (2)

In a spot welder configured to control the current provided to the electrode through the transformer by the ignition angle driven by the thyristor, A current measuring unit connected to the one end of the electrode and measuring a welding current between the electrodes; A voltage measuring unit connected to the one end of the electrode and measuring a welding voltage between the electrodes; Storage means for storing possible model dynamic resistance values of the nugget; The copper resistance value is detected using the welding current and the voltage, the next control current value is calculated using the copper resistance value and the model copper resistance value, and the ignition angle of the thyristors is controlled in response to the control current value. The current control apparatus of the spot welding machine using the dynamic resistance value provided with a control means. A method of controlling current in a spot welder having information about the possible model dynamic resistance values of the nugget, Sensing a welding current and a voltage value every cycle, and calculating dynamic resistance with these two values; Calculating the difference between the two values by comparing the copper resistance value with a model value of the copper resistance; Calculating a current value to be compensated by multiplying the calculated difference value by a predetermined constant; Setting the control current value by adding the calculated compensation current value to the model current value based on the dynamic resistance model value; And providing a welding current corresponding to the control current value.