JPH06142943A - Welding device - Google Patents

Abstract

PURPOSE:To obtain wide range and accurate welding current by variably control ling the winding ratio of a variable transformer. CONSTITUTION:The winding ratios of a welding gun part 1, a variable transformer part 2 to convert a primary voltage supplied from a timer contact part 3 to a secondary voltage, thyristors 9-1, 9-2, 9-3,... to vary the number of winding of a secondary coil of a variable transformer part 2, a secondary voltage value measuring part 14 to measure a secondary voltage of the variable transformer part 2 and the variable transformer part 2 at the start of welding are set to the maximum. On the other hand, when the secondary voltage is low, a transformer winding ratio enumerating part 15 to change the winding ratio of the variable transformer part 2 and a primary current control part 13 to control the primary current of the variable transformer part 2 based on the change of the winding ratio are provided well.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a welding apparatus, and more particularly to a welding apparatus suitable for use in variably controlling the winding ratio of a variable transformer for resistance welding.

[0002]

2. Description of the Related Art A conventional resistance welding apparatus, for example, as shown in FIG. 2, includes a thyristor 50 and a timer contactor 51 for controlling a welding primary power source (current, voltage) supplied from a power source (not shown). A welding transformer 53 for converting a primary power source (timer contactor power source) supplied from the timer contactor 51 via a cable 52 into a secondary power source, and a pair of electrodes to which the secondary power source is supplied from the welding transformer 53 via a cable 54. The welding gun 56 is provided with 55A and 55B. That is, in the conventional welding apparatus, the welding transformer 53 and the timer contactor 51 are completely separated and independent, and the winding ratio of the welding transformer 53 is fixed. Therefore, the current supplied to the primary side of the welding transformer 53 is controlled by the timer contactor 51 to control the current supplied to the welding gun 56 (secondary current of the welding transformer 53). FIG. 3 is a circuit configuration of the resistance welding device.

[0003]

However, in the case of the above-mentioned conventional resistance welding apparatus, since the winding ratio of the welding transformer 53 is constant, the secondary voltage of the welding transformer 53 becomes constant. Is usually set to a low voltage of a few V to a few tens of V, so that the welding gun 56 has a large pocket size and the secondary cable 54 of the welding transformer 53.
The length, the resistance due to the plate thickness of the materials to be welded, the contact resistance between the materials to be welded, the cable 5
Due to factors such as deterioration of 2, 53 due to aging, and the like, the ratio of the voltage drop accompanying the increase in impedance increases, and as a result, when the secondary voltage drops below a predetermined value, the welding gun 55 There was a problem that a constant current could not flow.

[0004]

It is an object of the present invention to improve the disadvantages of the above-mentioned conventional example, and in particular, by using a variable transformer having a variable winding ratio and controlling the winding ratio, a wider and more accurate welding current than the conventional one can be obtained. It is an object of the present invention to provide a welding device that achieves the above.

[0005]

In order to achieve the above object, the present invention is a welding apparatus configured to control a welding current supplied to an electrode of a welding gun, in which a fixed primary winding and a variable secondary winding are provided. A variable transformer having a winding and converting a primary voltage supplied from a welding current supply unit to a secondary voltage; and a number of turns of the secondary winding arranged on the secondary winding of the variable transformer. A secondary voltage measuring unit equipped with a variable number of turns variable means for measuring the secondary voltage of the variable transformer, and at the start of welding, the number of turns ratio of the variable transformer is set to the maximum by the number of turns variable means. A winding ratio control unit for changing the winding ratio of the variable transformer by the winding number changing means when the secondary voltage measured by the secondary voltage measuring unit is lowered, and the winding ratio control unit changes the winding ratio. A primary current control for controlling the primary current of the variable transformer based on Parts are made as a having a.

[0006]

According to the welding apparatus of the present invention, the winding ratio control section is
At the start of welding the materials to be welded together by the welding gun, the number of turns of the secondary winding of the variable transformer is varied by the number of turns varying means to set the number of turns of the variable transformer to the maximum. After the start of welding, when the secondary voltage of the variable transformer measured by the secondary voltage measuring unit drops, the turns ratio control unit changes the number of turns of the secondary winding of the variable transformer by the winding number changing means to change the primary winding. The current controller controls the primary current of the variable transformer. By the above, it is possible to increase the secondary voltage supplied from the variable transformer to the welding gun. Therefore, when the length and deterioration of the welding gun and the cable, and the increase in impedance due to the thickness of the material to be welded and the contact resistance occur. However, the rate of the voltage drop of the secondary voltage can be suppressed to the minimum, and the secondary current can be supplied to the welding gun in a more stable state than before. Further, since the allowable range of the electrode resistance value of the welding gun can be expanded, the life of the electrode can be extended, the cost can be reduced, and the selection range of the type of the welding gun can be expanded. Further, when the secondary current of a predetermined value is obtained, the primary current can be lowered by variably controlling the turns ratio of the variable transformer, so that energy saving can be achieved. Further, when the secondary voltage drops, the primary current is controlled, so that an accurate secondary current can be obtained.

[0007]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram of a resistance welding apparatus according to this embodiment. The resistance welding apparatus is a welding gun section 1 for performing resistance welding.
2, a variable transformer unit 2 having a variable winding ratio, a timer contactor unit 3 for controlling a welding primary power source supplied from a power source unit (not shown), and a control unit 4 for controlling each unit. . The resistance welding apparatus of the present embodiment supplies a wider and more accurate welding current to the welding gun unit 1 by controlling ON / OFF of a plurality of thyristors of the variable transformer unit 2 to change the winding ratio. The feature is that this is achieved.

The welding gun portion 1 is provided with a pair of electrodes 5 and 6 for sandwiching materials to be welded (not shown) to perform resistance welding. The variable transformer unit 2 includes a primary winding 7 and
The secondary winding 8 and a plurality of thyristors 9-1 each having an anode terminal connected to the secondary winding 8, a cathode terminal connected to the electrode 6, and a gate terminal connected to a gate selection pulse generator 16 described later,
9-2, 9-3, ... The timer contactor unit 3 has a thyristor 11 having an anode terminal connected to the power supply unit, a cathode terminal connected to the secondary winding 7, a gate terminal connected to the gate pulse generation unit 10, a cathode terminal connected to the power supply unit, and an anode terminal connected to the thyristor 11. A thyristor 12 having a gate terminal connected to the secondary winding 7 and a gate pulse generator 10 connected thereto.
And a gate pulse generator 10 for ON / OFF controlling the thyristors 11 and 12 based on a control signal from a primary current controller 13 described later. The control unit 4 includes a primary current control unit 13, a secondary voltage value measurement unit 14, a transformer turn ratio calculation unit 15, and a gate selection pulse generation unit 16.

To explain the configuration of the control unit 4 in detail, the primary current control unit 13 supplies the primary current supplied from the timer contactor unit 3 to the primary winding 7 of the variable transformer unit 2 to the welding gun unit 1. It is calculated according to the required secondary current, and the primary current is increased (when the secondary voltage is decreased) or decreased (when the primary current is increased) based on the changed winding ratio of the variable transformer unit 2 by the transformer winding ratio calculation unit 15. Control signal corresponding to the control primary current.
It is supplied to 0. Secondary voltage value measuring unit 14
Measures the secondary voltage supplied from the variable transformer section 2 to the welding gun section 1 and outputs the measured secondary voltage to the transformer turn ratio calculation section 1
5 is to be supplied.

The transformer turn ratio calculation unit 15 sets the turn ratio between the primary winding 7 and the secondary winding 8 of the variable transformer unit 2 to the maximum at the start of the turn ratio control, and the secondary voltage value measuring unit 14 measures the ratio. When the secondary voltage value drops, the turns ratio of the variable transformer unit 2 is lowered, and when the rise of the primary current reaches the limit, the turns ratio of the variable transformer unit 2 is slightly raised, and the control signal corresponding to the changed turns ratio is set. Is supplied to the gate selection pulse generator 16 and fed back to the primary current controller 13. The gate selection pulse generation unit 16 includes the thyristors 9-1, 9-2, 9-3, ... Of the variable transformer unit 2.
ON / OFF control is performed, and a gate selection pulse is supplied to the gate terminal of the thyristor corresponding to the changed turns ratio, and the thyristor is turned on.

Here, the secondary voltage of the variable transformer section 2 of the resistance welding apparatus can be expressed by the following equation: v2 = (nx / n1) v1 (where v1: primary voltage, nx: secondary winding). The number of turns of the wire, n1: the number of turns of the primary winding), and the secondary voltage vary depending on the turns ratio. On the other hand, the secondary current of the variable transformer unit 2 is i2 = (v1 / v2) i1 = (n1 / nx) i1,
Although it can be expressed by the following equation, when the resistance value R in the welding gun portion 1 and the like is taken into consideration, it can be expressed by the following equation: i2 = v2 / R. Therefore, when the resistance value R in the welding gun section 1 or the like becomes large, it becomes difficult for the secondary current to flow. However, in the present embodiment, the winding ratio of the variable transformer section 2 is variably controlled to increase the secondary voltage and the primary current is increased. By also raising the temperature, a wider and more accurate welding current can be supplied to the welding gun section 1 than in the conventional case.

Next, the turn ratio control operation in the resistance welding apparatus of the present embodiment having the above-mentioned structure will be described.

When resistance welding of the materials to be welded is performed by the resistance welding device, the transformer winding number ratio calculation unit 15 of the control unit 4 is used.
First, the control signal for maximizing the winding ratio of the variable transformer section 2 is supplied to the gate selection pulse generating section 16. As a result, the gate selection pulse generation unit 16 supplies the gate selection pulse to the thyristor 9-1 of the variable transformer unit 2 to turn on the thyristor 9-1, so that the winding ratio of the variable transformer unit 2 is maximized. Is set. Next, the transformer turns ratio calculating unit 15 supplies the primary current from the timer contactor unit 3 to the primary winding 7 of the variable transformer unit 2 with the necessary secondary current supplied from the variable transformer unit 2 to the welding gun unit 1 as a reference. The current is calculated, and a control signal corresponding to the calculated primary current is supplied to the gate pulse generator 10 of the timer contactor unit 3. As a result, the gate pulse generator 10 controls ON / OFF of the thyristors 11 and 12 to supply the primary current from the timer contactor 3 to the variable transformer 2.

As the primary current is supplied from the timer contactor unit 3 to the variable transformer unit 2, the variable transformer unit 2
Converts the primary current into a secondary current and supplies it to the welding gun section 1. At this time, the secondary voltage value measuring unit 14 of the control unit 4 measures the secondary voltage value corresponding to the secondary current and supplies it to the transformer turns ratio calculating unit 15. Transformer turns ratio calculator 15
When the secondary voltage value is decreased, supplies a control signal for decreasing the turns ratio of the variable transformer section 2 to the gate selection pulse generation section 16 and the primary current control section 13. As a result, the gate selection pulse generator 16 is changed to the variable transformer 2
The gate selection pulse is supplied to the corresponding thyristor to turn on the corresponding thyristor, so that the winding ratio of the variable transformer unit 2 can be lowered. Further, the primary current control unit 13 supplies a control signal for increasing the primary current by an amount corresponding to the reduction of the turns ratio by the transformer turns ratio calculation unit 15, to the gate pulse generation unit 10 of the timer contactor unit 3. As a result, the gate pulse generator 10 causes the timer contactor unit 3 to
Since the gate pulse is supplied to the thyristors 11 and 12 for ON / OFF control, the primary current supplied from the timer contactor unit 3 to the variable transformer unit 2 increases.

On the other hand, the transformer turn ratio calculation unit 15 outputs a control signal for slightly increasing the turn ratio of the variable transformer unit 2 when the increase of the primary current reaches a limit, to the gate selection pulse generation unit 16 and the primary current control unit. 13 is supplied. As a result, the gate selection pulse generator 16 is changed to the variable transformer 2
Since the gate selection pulse is supplied to the corresponding thyristor to turn on the corresponding thyristor, the turn ratio of the variable transformer unit 2 can be increased. Further, the primary current control unit 13 supplies a control signal for reducing the primary current by an amount corresponding to the increase in the turns ratio by the transformer turns ratio calculation unit 15, to the gate pulse generation unit 10 of the timer contactor unit 3. As a result, the gate pulse generator 10 causes the timer contactor unit 3 to
Since the gate pulse is supplied to the thyristors 11 and 12 for ON / OFF control, the primary current supplied from the timer contactor unit 3 to the variable transformer unit 2 is reduced.

As described above, according to the resistance welding apparatus of this embodiment, the plurality of thyristors 9-of the variable transformer section 2 are provided.
Since the winding ratio is variably controlled by appropriately controlling ON / OFF of 1, 9-2, 9-3, ..., It becomes possible to increase the secondary voltage supplied from the variable transformer section 2 to the welding gun section 1.
Therefore, even if the impedance in the welding gun 1 increases, the impedance increases due to the length and deterioration of the cable, and the impedance increases due to the thickness of the material to be welded and the contact resistance, the ratio of the voltage drop in the secondary voltage due to the impedance increase It is possible to suppress it to the minimum, and as a result, the secondary current can be supplied to the welding gun section 1 in a more stable state than before.

Further, according to the present embodiment, since the allowable range of the resistance value (maximum resistance value) of the electrode of the welding gun portion 1 can be expanded as described above, the life of the electrode can be extended, The cost can be reduced and the selection range of the electrode type, that is, the welding gun type can be widened, and various welding guns can be used for a single variable transformer section 2 from small to large. You can

Further, according to this embodiment, when the secondary current of the predetermined value supplied from the variable transformer section 2 to the welding gun section 1 is obtained, the winding ratio of the variable transformer section 2 is variably controlled, From the timer contactor section 3 to the variable transformer section 2
Since the primary current supplied to the device can be reduced, energy can be saved.

Further, according to the present embodiment, the secondary voltage of the variable transformer section 2 is measured by the secondary voltage value measuring section 14, and when the secondary voltage drops, the primary current control section 13 changes the primary current to Due to the control, an accurate secondary current can be obtained.

[0021]

As described above, according to the present invention,
Since the winding ratio of the variable transformer is variably controlled, it is possible to increase the secondary voltage supplied from the variable transformer to the welding gun. Therefore, the length and deterioration of the welding gun and the cable, and the plate of the material to be welded. Even if impedance increases due to thickness or contact resistance, the ratio of the voltage drop of the secondary voltage can be suppressed to a minimum, which allows the secondary current to be supplied to the welding gun in a more stable state than before. Since the allowable range of the electrode resistance value of the welding gun can be expanded, the life of the electrode can be extended and the cost can be reduced, and the selection range of the welding gun type can be expanded. When a secondary current of a predetermined value is obtained, the primary current can be lowered by variably controlling the turns ratio of the variable transformer, and energy can be saved. , For controlling the primary current when the secondary voltage decreases, it is possible to provide a welding device which exerts such it is possible to obtain an accurate secondary current, various effects.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a resistance welding apparatus according to an embodiment of the present invention.

FIG. 2 is an external view of a resistance welding device of a conventional example.

FIG. 3 is a circuit diagram of a conventional resistance welding device.

[Explanation of symbols]

 1 Welding Gun Part 2 Variable Transformer Part 3 Timer Contactor Part 4 Control Part 5, 6 Electrode 7 Primary Winding 8 Secondary Winding 9-1, 9-2, 9-3 Thyristor 10 Gate Pulse Generator 11, 12 Thyristor 13 Primary current control unit 14 Secondary voltage value measurement unit 15 Transformer turn ratio calculation unit 16 Gate selection pulse generation unit

Claims (1)

[Claims] 1. A welding apparatus configured to control a welding current supplied to an electrode of a welding gun, the primary having a fixed primary winding and a variable secondary winding and supplied from a welding current supply section. A variable transformer for converting a voltage to a secondary voltage; and a winding number changing means arranged in the secondary winding of the variable transformer for changing the number of turns of the secondary winding. When the secondary voltage measuring unit that measures the secondary voltage and the winding number changing means sets the winding ratio of the variable transformer to the maximum at the start of welding, while the secondary voltage measuring unit decreases the secondary voltage. And a winding ratio control unit that changes the winding ratio of the variable transformer by the winding number changing unit, and a primary current control unit that controls the primary current of the variable transformer based on the change of the winding ratio by the winding ratio control unit. A welding device comprising: