JP2000202644A - Method for judging quality of ultrasonic welding - Google Patents

Abstract

PROBLEM TO BE SOLVED: To judge acceptance/rejection of a welded condition between members to be welded in an ultrasonic welding process. SOLUTION: In a process to achieve the ultrasonic welding by the ultrasonic wave to be given from a horn chip, the temperature of a welded part between a second member W2 to be welded and a first member W1 to be welded is measured, the temperature of a placement part of an anvil 12 on which the first member W1 to be welded is placed is measured, and the temperature of the welded part is compared with the temperature of the placement part to judge the quality of the ultrasonic welding. The quality of the ultrasonic welding can similarly judged by measuring the amplitude of the first member W1 to be welded and the second member W2 to be welded.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for judging whether welding conditions are good or not when performing ultrasonic welding between a horn tip and an anvil.

[0002]

2. Description of the Related Art Conventionally, as a general ultrasonic welding machine 1,
As shown in FIGS. 2A and 2B, the members to be welded W1, W2
A horn tip 3 to which ultrasonic vibration is applied is provided at a position above the anvil 2 on which the horn chip 3 is placed.
To be welded and the anvil 2 to be welded W1, W2
And ultrasonic welding is carried out (Japanese Utility Model Application Laid-Open No. 56-142891). Then, the normal anvil 2 is firmly fixed to the base block 4, and the first welded member W1 mounted on the anvil 2 is also fixed to the anvil 2.
, The first member to be welded W1 is configured to be integrated with the anvil 2. By doing so, the second welded member W2 that is pressed by the horn tip 3 and vibrates integrally with the horn tip 3, and the first welded member W1 that is fixed to the anvil 2 and is stationary And the strongest vibration can be applied between them. Therefore, it is known that heat is generated effectively in this portion, and as a result, excellent ultrasonic welding is performed.

As a method for determining whether or not ultrasonic welding has been effectively performed, a monitoring method described in Japanese Patent Application Laid-Open No. 5-115986 is known. In this method, a pickup is attached to an anvil, ultrasonic vibration leaking to the anvil is detected, and the quality of ultrasonic welding is determined by analyzing the waveform of the vibration.

[0004]

However, in the monitoring method based on the ultrasonic leak vibration to the anvil, as described above, the first member to be welded is securely fixed to the anvil and integrated. Unless it is assumed that there is a good or bad, accurate judgment of good or bad cannot be obtained. That is, when slippage occurs between the first member to be welded and the anvil, the first member to be welded is ultrasonically vibrated together with the second member to be welded, resulting in good welding. Absent. Therefore, the monitoring method described above cannot accurately determine a welding defect in such a situation.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to make it possible to accurately determine the quality of ultrasonic welding due to the effect of the fixed state of a non-welded member fixed on an anvil. And

[0006]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention is directed to a first embodiment in which a first member to be welded mounted on an anvil and a first member to be welded are superposed on the first member to be welded. In the step of ultrasonically welding the second member to be welded and pressed by the horn tip by the ultrasonic wave applied from the horn tip, the second member to be welded and the first member to be welded are welded to each other. In addition to measuring the temperature of the welded portion between, the temperature of the mounting portion of the anvil on which the first member to be welded is mounted is measured, and the temperature of the welded portion and the temperature of the mounting portion are respectively set to a reference value and a reference value. There is provided a method for determining the quality of ultrasonic welding, wherein the quality of ultrasonic welding is determined by comparing.

Specifically, it is preferable that the measurement of the temperature of the welding portion and the temperature of the mounting portion are performed in a state where the measurement portion is not in contact with the measurement portion. We use a total meter. According to the above method, as a result of the temperature measurement, when the temperature of the welding portion is higher than the reference value and the temperature of the mounting portion is lower, the first member to be welded is firmly fixed to the anvil, and as a result, , First
Heat generation by effective ultrasonic vibration occurs between the member to be welded and the second member to be welded, and it is determined that satisfactory ultrasonic welding has been performed. On the other hand, as a result of the temperature measurement, when the temperature of the welded portion is lower and the temperature of the mounting portion is higher than the reference value, the first member to be welded is not sufficiently fixed to the anvil and slippage occurs. It is determined that the ultrasonic welding at that time is defective. Also, as a result of the temperature measurement, when the temperatures of the welded portion and the mounting portion are respectively lower than the reference values, it is determined that slippage has occurred between the second welded member and the horn tip, Sonic welding is determined to be defective.

According to the second aspect of the present invention, the first member to be welded mounted on the anvil, and the second member to be welded superposed on the first member to be welded and pressed by the horn tip are provided. In the step of ultrasonic welding by ultrasonic waves applied from the horn tip, the amplitude of the first member to be welded and the amplitude of the second member to be welded are respectively measured, and the amplitude of the first member to be welded and A method for determining the quality of ultrasonic welding is characterized in that the quality of ultrasonic welding is determined by comparing the amplitude of the second member to be welded with a reference value.

More specifically, the measurement of the amplitude of the first and second members to be welded is preferably performed in a non-contact state with respect to a measurement portion. For example, a laser Doppler vibrometer may be used. ing. According to the above method, when the amplitude of the first member to be welded is smaller than the reference value and the amplitude of the second member to be welded is larger than the reference value, the first member to be welded is Then, heat is generated between the second member to be welded and the effective ultrasonic vibration, so that it is determined that satisfactory ultrasonic welding has been performed. On the other hand, when the amplitudes of the first member to be welded and the second member to be welded are both larger than the reference value, it is determined that the first member to be welded is not sufficiently fixed to the anvil and slippage occurs. In this case, in the welded portion between the first member to be welded and the second member to be welded, sufficient heat generation cannot be obtained due to insufficient relative vibration, and it is determined that welding is defective. Conversely, heat is generated between the first member to be welded and the anvil. Further, when both the amplitude of the first member to be welded and the amplitude of the second member to be welded are smaller than the reference value,
It is determined that slippage has occurred between the second member to be welded and the horn tip. Also in this case, sufficient heat is not obtained due to insufficient relative vibration in the welded portion, and it is determined that welding is defective. You.

[0010] In the present invention, the welding state of the welded portion between the first and second members to be welded can be accurately grasped as described above. In addition, by measuring the temperature or amplitude for determining the quality of the welding state in a non-contact state with the member to be welded, stable data is always obtained regardless of the size and shape of the member to be welded. be able to.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a first embodiment, in which a bus bar made of a copper plate is a first member to be welded W1 and a core wire of a terminal of an electric wire is a second member to be welded W2, and these are welded by an ultrasonic welding machine 11 as an example. , The first member to be welded W1 is placed on the anvil 12 and the second member to be welded W2 is placed thereon.
Are superposed, and they are sandwiched by the horn tip 13 and ultrasonically welded.

In the vicinity of the ultrasonic welding machine 11, radiation thermometers 14, 15 capable of measuring the temperature of an arbitrary spot in a non-contact manner by detecting far infrared rays are arranged. Then, one radiation thermometer 14 sets and installs a spot on the mounting portion 12a of the anvil 12 on which the first member to be welded W1 is mounted, and the other radiation thermometer 15 sets the second welding member W1. A spot is set and installed at a welding portion Wa between the member W2 and the first member to be welded W1. That is, the mounting portion 12a and the welding portion W
The temperature of a can be individually measured by the radiation thermometers 14 and 15.

[0013] The temperature data measured by the radiation thermometers 14 and 15 is input to a pass / fail judgment device 16, where it is compared with a predetermined reference value at each site to determine whether the welding condition is good or bad. The determination is made and the result is issued as a signal such as an alarm. The reference value is registered in advance as the temperature of the welded portion Wa and the mounting portion 12a during the welding process of the sample on which the excellent ultrasonic welding has been performed.

In order to perform welding using the ultrasonic welding machine 11, a bus bar as the first member to be welded W1 is mounted on the mounting portion 12a of the anvil 12 at a position where the horn tip 13 is raised. Then, the core wire of the wire end is superimposed on the first member to be welded W1 as the second member to be welded W2 on the first member to be welded W1. From this state, the horn tip 13 is lowered to sandwich and press the first member to be welded W1 and the second member to be welded W2 between the anvil 12 and simultaneously apply ultrasonic vibration. Then, ultrasonic vibration is directly applied from the horn tip 13 to the second member to be welded W2.

While the ultrasonic vibration is applied from the horn tip 13, the radiation thermometers 14 and 15 measure the temperatures of the mounting portion 12a and the welding portion Wa. Then, the temperature data is input to the pass / fail determination device 16, where:
It is compared with each reference value. As a result, when the temperature of the welded portion Wa is higher and the temperature of the mounting portion 12a is lower than the reference value, it is determined that excellent ultrasonic welding is being performed. That is, in such a state, the first member to be welded W
1 is firmly fixed to the anvil 12, and
It is determined that sufficient ultrasonic vibration is applied between the second member to be welded W1 and the first member to be welded W1 without the second member W2 being pressed by the horn tip 13 and causing a slip.

On the other hand, when the temperature data of the welding portion Wa is lower than the reference value and the temperature of the mounting portion 12a is higher than the reference value, it is determined that the welding is defective. That is, in this embodiment, it is determined that the first workpiece W1 is not sufficiently fixed to the anvil 12 and slipping occurs, and as a result, the first workpiece W1 and the second workpiece W2 are separated. Vibration occurs integrally, and heat generation at the welded portion 12a becomes insufficient.

Also, as a result of the temperature comparison, when the temperatures of the welding portion Wa and the mounting portion 12a are lower than the reference values, it is also determined that the welding is defective. In this case, the second member to be welded W2
And the horn tip 13 slips, so that sufficient ultrasonic vibration cannot be applied to the welded portion Wa.

FIG. 2 shows a second embodiment. In this embodiment, the quality of ultrasonic welding is determined by measuring the amplitudes of the workpieces W1 and W2 and comparing them with a reference value. ing. For this reason, laser Doppler vibrometers 24 and 25 are arranged near the ultrasonic welding machine 11 to enable non-contact measurement. This vibrometer 2
Reference numerals 4 and 25 detect the vibration speed of the measurement target based on the difference in frequency between the reflected beam that has undergone dot shift by irradiating the measurement target with the laser beam and the laser beam at the time of incidence. And by the differential integration function,
Acceleration and displacement can be obtained, and furthermore, a vibration waveform can be displayed in combination with a digital oscilloscope.

Then, a laser beam is irradiated from one vibrometer 24 toward the first workpiece W1 on the anvil 12, and a laser beam emitted from the other vibrometer 25 is pressed by the horn tip 13. The mounting position is adjusted so that the second member to be welded W2 is irradiated.

As in the first embodiment, during the ultrasonic welding of the first member to be welded W1 and the second member to be welded W2,
Laser Doppler vibrometers 24 and 25 irradiate a laser beam to each of first member W1 and second member W2 to be welded and measure their respective amplitudes. Compare with As a result, when the first member to be welded W1 is firmly fixed to the anvil 12, the amplitude of the first member to be welded W1 is smaller than the reference value, and the second member to receive ultrasonic vibration directly from the horn tip 13 is used. Becomes larger than the reference value. Accordingly, heat is generated by the effective ultrasonic vibration between the first member to be welded W1 and the second member to be welded W2, and it is determined that excellent ultrasonic welding has been performed.

On the other hand, the anvil 1 of the first workpiece W1
2 is not sufficiently fixed, slippage occurs between the anvil 12 and the first welded member W1, and the vibration meter 2
The measured value of the amplitude according to 4, 25 is the first welded member W
Both the first and second members to be welded W2 are larger than the reference value. In this case, it is determined that the relative vibration between the first member to be welded W1 and the second member to be welded W2 is insufficient, sufficient heat is not obtained, and that good ultrasonic welding is not performed. Is done. Conversely, heat is generated between the first welded member W1 and the anvil 12.

When the pressing by the horn tip 13 is insufficient and slippage occurs between the second member to be welded W2 and the horn tip 13, the first member to be welded W1 and the second member to be welded are not slid. The relative vibration between the welding member W2 and the welding member W2 is insufficient, and both become smaller than the reference value. Therefore, sufficient heat is not obtained, and it is determined that good ultrasonic welding is not performed in this case as well.

[0023]

As is apparent from the above description, according to the ultrasonic welding pass / fail determination method of the present invention, the temperature or amplitude of a specific portion is measured and compared with a reference value. The quality of the ultrasonic welding can be accurately determined. At this time, as a cause of poor welding, it is possible to grasp for each factor whether slip occurs between the first welded member and the anvil or slip occurs between the horn tip and the second welded member. Therefore, it is possible to effectively take measures against defects.

[Brief description of the drawings]

FIG. 1 is a diagram showing a measurement state according to a method for determining the quality of ultrasonic melting according to a first embodiment of the present invention.

FIG. 2 is a diagram illustrating a measurement state according to a method for determining the quality of ultrasonic melting according to a second embodiment of the present invention.

FIGS. 3A and 3B are diagrams showing a conventional example.

[Explanation of symbols]

 W1, W2 Member to be welded Wa Welding part 11 Ultrasonic welding machine 12 Anvil 12a Placement part 13 Horn tip 14, 15 Radiation thermometer 24, 25 Vibration meter

Claims (2)

[Claims] 1. A horn tip comprising: a first member to be welded mounted on an anvil; and a second member to be welded superposed on the first member to be welded and pressed by a horn tip. In the step of ultrasonic welding by the ultrasonic wave applied from the above, while measuring the temperature of the welded portion between the second member to be welded and the first member to be welded, and mounting the first member to be welded The temperature of the mounting portion of the anvil to be placed is measured, and the quality of the ultrasonic welding is determined by comparing the temperature of the welding portion and the temperature of the mounting portion with reference values, respectively. Quality judgment method of ultrasonic welding. 2. A horn tip, comprising: a first member to be welded mounted on an anvil; and a second member to be welded superimposed on the first member to be welded and pressed by a horn tip. In the step of performing ultrasonic welding by ultrasonic waves given from the above, the amplitude of the first member to be welded and the amplitude of the second member to be welded are measured, and the amplitude of the first member to be welded and the second member to be welded are measured. A method for determining the quality of ultrasonic welding, wherein the quality of ultrasonic welding is determined by comparing the amplitude of each member with a reference value.