CROSS-REFERENCE TO RELATED APPLICATIONS

[0001] This application claims the benefit of and priority to U.S. Patent Application Serial No. 16/352,082, filed March 13, 2019 and U.S. Provisional Patent Application Serial No. 62/783,459, filed December 21, 2018, each of which is hereby incorporated by reference herein in its entirety.

BACKGROUND

[0002] An ultrasonic welding method is disclosed in US patents 8,052,816 and 9,486,955, in which the movement of the ultrasonic welding stack is delayed, following the initiation of the weld, until a predetermined condition is satisfied. During this delay, the speed of movement of the ultrasonic welding stack is zero as the stack is maintained at a stationary position. Similar methods for delaying motion, after some weld motion has already occurred, are disclosed in US patents 9,144,937 and 9,849,628. Likewise, the speed of the ultrasonic welding stack in these methods is zero during the delays.

[0003] While the methods referenced above are beneficial in achieving high quality ultrasonic welds in the majority of applications, they can have undesirable consequences in some applications. In particular, in cases where the plastic material softens very quickly once ultrasonic energy is imparted to the workpieces being welded, the force between the workpieces decreases rapidly. This decrease can continue even after the predetermined condition for moving the ultrasonic welding stack is satisfied since this movement does not occur instantaneously due to various electrical and mechanical limitations of the motion system used to drive the movement of the stack, such as the limited rate at which electrical current can be ramped up in a motor. If the contact force between the workpieces becomes too low, the ultrasonic vibrations are not transmitted properly from the stack to the weld joint, potentially resulting in scuffing or marking of the surface of the workpiece in contact with the ultrasonic horn, a notable increase in audible noise during the welding process, and a reduction in the consistency of weld quality.

BRIEF DESCRIPTION OF THE DRAWINGS

[0004] FIG. 1 shows graphs of the Distance traversed by an ultrasonic welding stack from the start of the weld, the Speed of movement of the stack, and the Force applied by the stack to workpieces versus time for a representative weld phase; [0005] FIG. 2 shows graphs of Distance, Speed, and Force versus Time for welding of the same workpieces described in connection with FIG. 1, except using the prior art method of delayed motion;

[0006] FIG 3 shows the graphs of FIG. 1 and FIG. 2 superimposed on one another for the purposes of direct comparison;

[0007] FIG 4A shows a linearly increasing speed profile, where the initial speed is zero;

[0008] FIG 4B shows a linearly increasing speed profile, where the initial speed is non-zero;

[0009] FIG 4C shows the speed as a second order polynomial function of time; and

[0010] FIG 5 shows graphs of Ultrasound Power and Speed versus Time, where the speed is directly proportional to the ultrasound power.

DESCRIPTION

[0011] The concepts described below are alternatives and improvements to the methods of delaying weld motion disclosed in prior art to remedy the aforementioned undesirable consequences of the disclosed methods.

[0012] In one embodiment of the new concepts, the same ultrasonic welding method as described in US patent 8,052,816 claim 1 is used, except that instead of moving the ultrasonic welding stack only after the signal corresponding to the monitored control variable satisfies a predetermined condition, the ultrasonic stack is moved at a low, constant speed at the initiation of the welding operation, with this speed being maintained until the predetermined condition is satisfied. An example of this method is illustrated in FIG. 1, which shows graphs of the Distance traversed by the ultrasonic welding stack from the start of the weld, the Speed of movement of the ultrasonic welding stack, and the Force applied by the ultrasonic welding stack to the workpieces versus time for a representative weld phase, which begins at Time 0 and ends at Time t3. The predetermined positive initial force is designated as Fi. At the initiation of the welding operation, the speed of the stack is a low, constant level Si. This speed is maintained until the predetermined condition is satisfied, which in this example is when the force decreases by the amount AFd relative to the initial force Fi, occurring at tl . Upon satisfaction of the condition, the motion control system commands the ultrasonic welding stack to move according to a weld profile, which in this example is an increase in speed to Sw, followed by maintaining a constant speed Sw. The actual change in speed from Si, however, does not occur instantly due to the aforementioned electrical and mechanical limitations of the motion system. Instead, the actual change in speed begins some time after the predetermined condition is satisfied, which is represented at t2. This motion system response delay is designated in the figure as DT. In this example, the weld ends when the distance traversed by the ultrasonic welding stack from the start of the weld reaches the predetermined level De. It should be noted, however, that this method of using a low initial weld speed is not limited to the particular weld profile and method for ending the weld cited in this example. Practical values of the initial speed Si are generally less than half of the average speed of the weld motion subsequent to the satisfaction of the predetermined condition.

[0013] The benefits of using this technique are illustrated in FIGS. 2 and 3. FIG. 2 shows graphs of Distance, Speed, and Force versus Time for welding of the same workpieces described in connection with FIG. 1, except using the prior art method of delayed motion. The speed of the ultrasonic stack is zero until the same predetermined condition is satisfied, consisting of the decrease in the force relative to the initial force by AFd, occurring at t4. Upon satisfaction of the condition, the motion control system commands the ultrasonic welding stack to move according to the same weld profile, consisting of a change in speed to Sw, followed by maintaining a constant speed Sw. In addition, the same motion system response delay DT exists, whereby the actual start of motion occurs at t5, which is DT after the predetermined condition is satisfied. As in FIG. 1, the weld ends when the distance traversed by the ultrasonic welding stack reaches De.

[0014] FIG. 3 shows the graphs of FIG. 1 and FIG. 2 superimposed on one another for the purposes of direct comparison. The solid curves are the same as those shown in FIG. 1 representing the low initial weld speed method, and the long dashed lines are the same as FIG. 2 representing the prior art motion delay method. The primary benefit of the low initial speed method is that the decrease in force between the workpieces relative to the initial force Fi is smaller compared to the motion delay method. In the Force versus Time graph of FIG. 3, the force decrease for the low initial weld speed method is AFl, which is smaller than the decrease for the motion delay method AF2. The reason for this difference is that during the motion system response delay (DT), which is common to both methods, the workpieces continue to be collapsed against each other in the low initial weld speed method, which mitigates the decrease in force compared to the motion delay method, where there is no workpiece collapse during the delay. Thus the occurrence of the undesirable effects stemming from the contact force between the horn and workpieces becoming too low is less likely using the low initial weld speed method. Another benefit of this method is that it can lead to a decrease in the duration of the weld, and therefore an increase in production throughput. In the examples depicted in FIG. 3, the weld was shorter for the low initial weld speed method by the amount t6-t3. [0015] The low initial weld speed is not restricted to being constant as depicted in the example above. It can be a variety of different linear or non-linear functions of time or other parameters associated with the weld process, such as the power being output from the ultrasonic welding stack to the workpieces. Several examples are illustrated in FIG. 4, which show graphs of Speed versus Time from the initiation of the weld process at Time 0 until the predetermined condition is satisfied at tc. FIG. 4A shows a linearly increasing speed profile, where the initial speed is zero. FIG. 4B shows a linearly increasing speed profile, where the initial speed is non zero. FIG. 4C shows the speed as a second order polynomial function of time. FIG. 5 shows graphs of Ultrasound Power and Speed versus Time, where the speed is directly proportional to the ultrasound power. Regardless of the function, the average speed of motion, from the initiation of the weld until the predetermined condition is satisfied, is generally less than half of the average speed of the weld motion from the predetermined condition being satisfied to the end of the weld.