EP3938135A1 - Method for detecting the making or breaking of contact between a sonotrode and a counter-element - Google Patents

Abstract

The invention relates to a method for detecting the making or breaking of contact between a sonotrode (4), which is caused to oscillate with a frequency f and an oscillation amplitude A0, and a counter-element (5). According to the invention, in order to provide a method by means of which the making or breaking of contact between a sonotrode and a counter-element can be detected particularly quickly and economically, the method comprises the following steps: (a) capturing a time curve of the oscillation amplitude A0 (1) during a first measurement time interval ΔT and (b) determining, from the time curve of the oscillation amplitude A0 (1), whether a making or breaking of contact occurred within the measurement time interval ΔT.

Description

Method for the detection of a coming into or out of contact of a sonotrode with a

Counter element

The present invention relates to a method for detecting a coming into or out of contact of a sonotrode, which is set in oscillation with a frequency f and an oscillation amplitude Ao, with a counter element. In particular, the present invention relates to a method for the detection of a sonotrode coming into contact with a counter-tool, a material to be processed being able to be arranged between the sonotrode and the counter-tool. In addition, the present invention relates to a method for controlling an ultrasonic vibrating device.

Ultrasonic oscillating devices generally have at least one sonotrode, which can be set into mechanical oscillation as intended. In ultrasonic welding with an ultrasonic welding device or in ultrasonic cutting with an ultrasonic cutting device, a counter tool is arranged opposite the sonotrode and the material to be processed is arranged between the sonotrode and the counter tool. The material is then provided with a weld seam or cut by the sonotrode, depending on the area of application.

If a cut has been successfully completed during ultrasonic cutting or if the end of a material web is reached during ultrasonic welding, the sonotrode and the counter tool come into contact.

Such touching or collision of the sonotrode and counter tool, which occurs during operational vibration of the sonotrode, is an undesirable effect, since both the sonotrode and the counter tool are made of hard materials, so that the counter tool and sonotrode collide or rub against one another a strong Ver wear caused by these two elements.

On the other hand, when the sonotrode and the counter tool come into contact, certain process events are indicated. When cutting with an ultrasonic cutting device, the coming into contact of the sonotrode and the counter-tool indicates that the material to be cut has been severed. When welding with an ultrasonic welding device, coming into contact between the sonotrode and the counter-tool can accordingly indicate an unintentional severing of the material. In both applications, the sonotrode and counter-tool can also come into contact indicate the reaching of an end of a material web guided along between the sonotrode and the counter tool.

Particularly when cutting with an ultrasonic cutting device, it is important for process reliability and the quality of the products to be processed to be able to determine the point in time at which the sonotrode and the corresponding counter tool touch, as this allows appropriate measures to be taken. A distinction must be made between the time at which contact actually takes place and the time at which the contact is determined and located. The time in between is referred to as the acquisition time in the context of the present invention. A reaction to the contact can only take place after the acquisition time has elapsed, so that the response time is greater than or equal to the acquisition time.

Up to now, ultrasonic cutting processes were mostly simply carried out until a certain predefined running time or a certain predefined energy consumption was reached, for which previous experience had shown for the respective application that the cutting process was after this running time or after Achieving this energy consumption is complete. However, these methods are not particularly precise and require a long lead time in which sufficient experience or measurements must first be gathered for a specific application.

As an alternative, so-called metal contact electronics were used, in which the coming into contact of the sonotrode and counter-tool was detected, similar to a relay switch, via an additional DC voltage applied from outside. However, such a method requires additional sensors or electronics and is therefore associated with greater effort and higher costs. The acquisition times of such methods are 2 ms or more. This is too long for many applications.

In addition to determining whether a sonotrode comes into contact with a counter-tool, it is also desirable that a sonotrode and a counter-tool and a sonotrode come into contact with or out of contact with another counter-element can. The detection of such events with additional sensors, however, often takes too long or is too complex.

Against this background, the object of the present invention is to provide a method with which a sonotrode coming into or out of contact with a counter-element can be detected, the method eliminating or at least reducing the problems mentioned. In- In particular, it is the object of the present invention to provide a method which determines the point in time when a sonotrode comes into contact with a counter-tool with a detection time of less than 1 ms and is also inexpensive.

The object on which the invention is based is achieved by a method according to claim 1. The subject matter of claim 1 is a method for the detection of a coming into or out of contact of a sonotrode, which is set in an oscillation with a frequency f and an oscillation amplitude Ao, with a counter element with the steps: a) Detection of a time Course of the oscillation amplitude Ao during a first measurement period DT, b) determining from the time course of the oscillation amplitude Ao whether contact has been made within the measurement period DT.

In comparison to the previously known methods, which were aimed exclusively at detecting a stepping into contact, the method according to the invention can also be used to detect stepping out of contact. This can be important, for example, when processing multilayer systems with ultrasound, if the severing of an internal harder layer (i.e. the stepping out of contact with this harder layer) is to be detected.

The oscillation is preferably a periodic oscillation and in particular a harmonic oscillation. Assuming a harmonic oscillation with the frequency f, the deflection A (t) of the oscillation depends on the time t in the usual way

A (t) = A ₀ (t) cos (2 p / t) together with the oscillation amplitude Ao. In the ideal state, the sonotrode vibrates with a constant vibration amplitude Ao _. The oscillation amplitude changes, however, when the coupling between the sonotrode and the counter tool or between the sonotrode and the material to be processed changes, so that the oscillation amplitude is then also a time-dependent variable Ao (t). The present invention makes use of this.

With the method according to the invention, the point in time of stepping into or out of contact is determined significantly faster than is the case with the methods known from the prior art. The method according to the invention thereby allows shorter acquisition times of 100 ps and less. The consequence of this is that a reaction is also quicker to a coming into or out of contact between the counter element and the sonotrode, in particular the counter tool and the sonotrode can. Consequently, the method according to the invention creates the possibility of reacting with very short reaction times to the sonotrode and counter-element coming into or out of contact.

The reaction time is to be understood as the time between the actual point in time of stepping into or out of contact and the point in time of a reaction directed to it, such as, for example, calling up a control command.

In a preferred embodiment, step b) of the method according to the invention determines whether the sonotrode has come into or out of contact with the counter-element if the detected vibration amplitude Ao deviates from a predetermined reference amplitude R by more than a predetermined tolerance value a or if the detected vibration amplitude Ao is outside a predetermined tolerance interval [T _m m, _m T ax] is located.

Consequently, this embodiment provides a tolerance range which is either defined by a reference amplitude R and a tolerance value a or a tolerance interval [T _m m, _m T ax]. This tolerance range is a contiguous sub-range of the possible oscillation amplitude. It has been shown that such a tolerance range can be defined for each vibrating sonotrode of an ultrasonic vibrating device, so that the vibration amplitude when the sonotrode and counter-element come into contact or out of contact, and in particular when the sonotrode and counter-tool come into contact lies outside a definable tolerance range and otherwise lies within this tolerance range in the case of regular oscillation without the sonotrode and counter-element coming into or out of contact.

An in-or-out of contact is preferably only established when the oscillation amplitude leaves the tolerance range.

This has the advantage that the transient process of the ultrasonic oscillating device does not have to be dealt with separately. During the settling of a sonotrode, the vibration amplitude can assume values outside a predefined tolerance range, although the sonotrode and the counter-element do not come into or out of contact accordingly. The determination of a coming into or out of contact according to the preferred embodiment discussed here, however, presupposes that the oscillation amplitude leaves the tolerance range. As a rule, however, the oscillation amplitude does not assume values within the tolerance range until the transient process has ended. Therefore, the requirement of “leaving” ensures that an incorrect determination of an in or out of contact does not occur during the transient process. In order to form a redundant system which minimizes the risk of a false positive determination of getting into or out of contact, the measurement period DT is also preferably designed such that a transient process of the sonotrode is completed before the start of the measurement period DT.

The use of a tolerance range to determine when the sonotrode and the counter-element come into or out of contact is particularly advantageous, since this means that the determination of the coming into or out of contact is very simple and quick and there are no time-consuming calculations Based on the time course of the oscillation amplitude must be carried out, which would increase the detection time and the potential response time. Rather, coming into or out of contact is determined directly by the fact that the oscillation amplitude lies outside the tolerance range or leaves the tolerance range.

In a particularly simple embodiment, the reference amplitude can simply be the previously recorded measured value. As soon as the difference between the current measured value and the previous measured value (as reference amplitude) becomes greater than a predetermined tolerance value a, this is interpreted as coming into contact (or as stepping out of contact). The tolerance value a can be based on empirical values.

In order to be able to ignore short-term changes in the oscillation amplitude, it can be advantageous if the measurement signal of the oscillation amplitude is passed through a low-pass filter.

In a particularly preferred embodiment, prior to step a) during a second measurement period Dί, a time profile of the oscillation amplitude Ao is recorded and the reference amplitude and / or the tolerance interval are calculated from the detection during the second measurement period Dί.

In this embodiment, the tolerance range is advantageously determined during operation without a previous determination or adjustment of the ultrasonic oscillating device. As a result, there is an automated self-calibration of the ultrasonic oscillating device, which is always adapted to the ongoing operation or to the oscillation during ongoing operation, so that the appropriate reference amplitude does not have to be set externally for different ultrasonic oscillating devices or different applications or different external circumstances. This simplifies handling and improves the efficiency of the ultrasonic oscillating device in question. In particular with regard to the detection of a sonotrode coming into contact with a counter tool, there are known periods of time in many ultrasonic applications, such as ultrasonic welding or ultrasonic cutting, within which the sonotrode does not come into contact with the counter tool under normal circumstances is expected. The embodiment discussed here makes it possible to use one or more of these time periods as a second measurement period in order to define the reference amplitude for the tolerance range.

In the case of corresponding methods for detecting a sonotrode coming into contact with a counter-tool, the second measurement period is therefore preferably selected such that no contact between the sonotrode and counter-tool is to be expected within the second measurement period.

A further embodiment provides that a mean oscillation amplitude is calculated from the detection during the second measurement period At and the calculated mean oscillation amplitude is used in step b) as a predetermined reference amplitude. Using a mean value of the oscillation amplitude, which is calculated during operation, as the reference amplitude ensures that the tolerance range resulting from the reference amplitude and the tolerance value is always precisely adapted to ongoing operation.

In a further embodiment of the sensing during the second measurement period At a minimum vibration amplitude Amin and a maximum vibration amplitude A _m ax determined, from the minimum vibration amplitude amine and the maximum vibration amplitude Amax the tolerance interval with T _m in amine and T _m ax AEA _ma x is calculated. This embodiment ensures in particular that the tolerance range formed by the tolerance interval includes all values of the oscillation amplitude which do not indicate the sonotrode coming into or out of contact with a counter-element. The tolerance interval is always adapted to the special circumstances in the company. In this way, the tolerance interval of a single ultrasonic cutting device can adapt dynamically due to different external circumstances. For example, the tolerance interval in a first cutting process can be made wider than in a subsequent second cutting process.

For a process that is repeated over and over again, which is carried out by an ultrasonic oscillating device, the above-mentioned embodiments for the automated determination of the reference amplitude and / or the tolerance interval are preferably carried out once or only a few times. Subsequently, the reference amplitudes and / or tolerance intervals determined in this way are used for other similar processes for which no changes in the external circumstances are to be expected. Under processes of an ultrasonic oscillating device are in particular cutting processes of an ultrasonic cutting tool and welding processes of an ultrasonic welding tool to be understood.

A preferred embodiment provides that in step a) the sonotrode is excited by a converter, the converter being connected to a power generator and the current IE (t) provided by the power generator and flowing through the converter being measured, where the from the voltage UE (t) applied to the converter is measured from the power generator, and the oscillation amplitude or a field variable of the electrical oscillation system related to the oscillation amplitude consisting of the measured voltage UE (t) and the measured current IE (t) the power generator and the converter.

In particular, the oscillation amplitude can be determined using a method known from WO 2013/017452 A2.

The power generator is preferably a generator and provides a periodically changing voltage, preferably an alternating voltage, which is preferably converted into a mechanical vibration in a converter with a piezoelectric element, so that a standing wave is formed within a freely vibrating ultrasonic vibration device, whereby the sonotrode and the applied voltage are designed such that the position of a wave mountain of the standing wave corresponds to the position of a front surface of the sonotrode. The frequency of the applied periodically changing voltage is the excitation frequency, which is selected such that it corresponds to a resonance frequency of the freely oscillating, i.e. H. corresponds to ultrasonic vibrating device not in contact with other elements.

Taking into account the embodiment discussed here, the present invention is based, inter alia, on the knowledge that when the sonotrode and counter-element come into or out of contact, the oscillating structure of the entire ultrasonic oscillating device is modified in such a way that the resonance frequency of the ultrasonic oscillating device shifts . As a result, the excitation frequency and the resonance frequency no longer match. This in turn causes a change, such as a "tremor," i.e. H. an alternating rise and fall in the oscillation amplitude.

In a further embodiment, the method according to the invention has the following, further step c): c) Determination of a point in time to at which a step b) has come into or out of contact, from the time course of the oscillation amplitude, the point in time at which the oscillation amplitude leaves the tolerance range for the first time within the measurement period, or a point in time offset from this point in time by a predefined correction time is defined as point in time t0 of the coming into or out of contact.

By determining the point in time, further optimization of the underlying process can advantageously take place.

The first alternative, in which the point in time at which the oscillation amplitude within the measurement period leaves the tolerance range for the first time is defined as the point in time t0 of entering or out of contact, represents a particularly simple method for determining the point in time of the in-or-out Out of contact, which only requires a simple query of the vibration amplitude and a comparison with the tolerance range. In addition, no further method steps are necessary, so that by means of this preferred method a particularly fast and efficient determination of the point in time to the coming into or out of contact takes place.

With the second alternative, which provides a correction time, the point in time of coming into or out of contact can be determined very precisely and specifically as a function of knowledge, experience and measurements made with individual ultrasonic oscillating devices.

In one embodiment, a sampling rate of at least 2,000 samples / second, preferably of at least 5,000 samples / second and particularly preferably of at least 15,000 samples / second is used in step a) to determine the time profile of the vibration amplitude. In a preferred embodiment, a measured value was recorded every 50 ps, which corresponds to 20,000 samples / second.

The above-mentioned sampling rates ensure that the time between the point in time at which the oscillation amplitude actually leaves the tolerance range and the point in time at which it is determined that the tolerance range has been exceeded is sufficiently short. For example, with a sampling rate of 5,000 samples / second, there is always less than 200 ps between the point in time at which the oscillation amplitude actually leaves the tolerance range and the specific point in time at which the deviation from the tolerance range is detected, at a sampling rate of 10 000 samples / second always less than 100 ps and at a sampling rate of 20,000 samples / second always less than 50 ps. In a particularly preferred embodiment, a counter-tool is used as the counter-element, wherein a material to be processed can be arranged between the sonotrode and the counter-tool, and the contact between the sonotrode and the counter-tool is detected.

In this way, for example, during ultrasonic cutting, it can advantageously be detected when a cut has been completed, since the coming into contact of the sonotrode and the counter-tool indicates the success of a cutting process.

The object on which the invention is based is also achieved by a method for controlling an ultrasonic oscillating device, the ultrasonic oscillating device having a sonotrode and a counter tool, and the counter tool being arranged opposite the sonotrode during operation such that a material for processing by the sonotrode can be arranged between the sonotrode and the counter tool, with the steps:

A) Exciting the sonotrode with an oscillation for a predetermined period of time t _d , subsequently

B) performing the method according to claim 8 (according to the previously discussed embodiment

form, and

C) Stopping the excitation of the sonotrode or moving the sonotrode away from the counter tool, if contact between the sonotrode and the counter tool was detected in step B).

The contact between the sonotrode and the counter-tool determined by means of the method discussed above is used by the method described in this embodiment for controlling the ultrasonic oscillating device. The process steps are preferably carried out automatically.

Since the acquisition times of the previously discussed method according to the invention for determining the coming into contact of the sonotrode and counter-tool are significantly shorter than the acquisition times known from the prior art, the potential reaction time of the control command that is involved in determining the Contact-kicking follows, much shorter.

Since the coming into contact of the sonotrode and counter-tool under a vibrating sonotrode is associated with increased wear due to the colliding or rubbing against each other, the termination (switching off) of the excitation or the movement of the sonotrode after the first detected coming into contact the wear of the sonotrode and counter tool is limited to a minimum, whereby the usable Response time is significantly shorter - namely in the range of approx. 100 ps - than with the previously used methods that are based on metal contact detection. These methods result in a minimum response time of 2 ms that can be achieved on the basis of the acquisition times that can be achieved.

In a preferred embodiment of this method, step C) is only carried out after a predefined follow-up time t _N after the detection of contact, a reduction in the oscillation amplitude preferably being effected immediately after the detection of contact.

Such a predefined follow-up time t _N is particularly advantageous when the process of applying ultrasound, for example an ultrasonic welding process or an ultrasonic cutting process, is not completely concluded when the counter tool and sonotrode come into contact. In this way, the sonotrode and the counter-tool can come into contact in sections during a cutting process, although the material to be cut has not yet been 100% severed. It is therefore advantageous for ultrasonic oscillating devices that such a predefined delay time is provided and adjustable.

In addition, it can also occur that a contact is determined shortly before an actual contact occurs. In such a case, the acquisition time would be negative. In these cases, a follow-up time is also useful to ensure that the desired application, for example an ultrasonic cutting process, is successfully completed.

The oscillation amplitude is preferably steadily reduced within the follow-up time, so that the oscillation does not end abruptly but rather a "fading out" of the oscillation. As a result, the cutting edges are worked out particularly cleanly with ultrasonic welding and the weld seams with ultrasonic cutting.

In a particularly preferred embodiment, the start of the measurement period DT from the point in time at which the oscillation of the sonotrode begins (switched on) is only after a delay time t _{d has elapsed} , so that the oscillation of the sonotrode settles outside the measurement period DT.

As a result, the above-mentioned transient process of the sonotrode, within which the oscillation usually also lies outside a possibly defined tolerance range, is excluded from the measurement period, so that there is no false-positive determination of a contact based on the time course of the Amplitude of the oscillation of the Sonotrode can come. Such a definition of the measurement period is in most cases uncritical with regard to the risk of not determining a coming into contact outside the measurement period, since during the transient process the sonotrode and counter-tool come into contact with ultrasonic vibrating devices or ultrasonic sound - Applications are usually not to be expected.

All embodiments of the method according to the invention are preferably designed as computer-implemented methods.

In addition, the present invention also includes an ultrasonic oscillating device with a sonotrode, a counter-tool, wherein a material to be processed by the sonotrode can be arranged between the sonotrode and the counter-tool, and comprises means for executing a computer-implemented method according to one of the embodiments described above. The ultrasonic oscillating device preferably has a generator for providing a high-frequency electrical voltage, a converter with at least one piezoelectric element for converting the high-frequency electrical voltage into a mechanical vibration, the converter being connected to the sonotrode in such a way that a mechanical Transmits vibration of the converter to the sonotrode.

The ultrasonic oscillating device according to the invention is preferably an ultrasonic cutting device. In such ultrasonic cutting devices, it is particularly advantageous if the reaction time for controlling the ultrasonic oscillating device is particularly short as a result of a certain contact between the sonotrode and the counter tool, since the contact between the sonotrode and counter tool is synonymous with a The cutting process is complete. This allows cutting processes to be carried out more efficiently and in a way that is gentle on the tools.

The present invention further comprises a computer program comprising instructions which, when the program is executed by a computer or processor, cause the latter to execute a method according to one of the embodiments described above.

The invention also comprises a computer-readable storage medium comprising instructions which, when executed by a computer, cause the computer to execute a method according to one of the embodiments described above.

Further advantages, features and possible applications of the present invention will become clear from the following description of a preferred embodiment and the associated figure. Show it:

FIG. 1: a schematic representation of a sonotrode and an anvil before coming into contact (left) and when coming into contact and

Figure 2: a diagram of the time course of the oscillation amplitude of a sonotrode

Use of an embodiment of the method according to the invention.

A schematic representation of a sonotrode 4 and a counter tool 5 is shown in FIG. Between the sonotrode 4 and the counter tool 5, a material 7 to be cut Ma is arranged. The counter tool 5 has an elevation 6.

On the left-hand side of FIG. 1, the situation immediately before processing is shown. To cut through the material 7, the sonotrode 4 is moved in the direction of the counter-tool 5. The material 7 is compressed between the sonotrode 4 and the elevation 6 until the sonotrode 4 and elevation 6 touch, as shown on the right in FIG. When the elevation 6 comes into contact with the sonotrode 4, the material 7 is severed and the processing step is completed. In the state shown on the right in FIG. 1, the contact of the elevation 6 with the sonotrode 4 leads to a change in the vibration amplitude of the sonotrode 4, which is detected according to the invention.

FIG. 2 shows a two-axis diagram in which the time t is indicated on the horizontal axis and the oscillation amplitude Ao is indicated on the vertical axis. The line marked with the reference number 1 consequently represents the time profile 1 of the oscillation amplitude Ao.

The illustrated time profile 1 of the oscillation amplitude Ao is the time profile of the oscillation amplitude of a sonotrode of an ultrasonic cutting device in which a method according to the invention was used for detecting a sonotrode coming into contact with a counter tool. In the underlying cutting process, a material was arranged between the sonotrode and the counter-tool, which was then cut up by the sonotrode using ultrasonic machining. The time curve 1 shown in FIG. 2 shows the vibration amplitude Ao of the sonotrode from the point in time at which the sonotrode vibration used is started or switched on up to the point in time at which the sonotrode vibration ends.

In the time curve 1 of the oscillation amplitude Ao, the transient process can be seen in the left-hand area, in which the oscillation amplitude Ao of the sonotrode initially changes from a zero position rises steadily before it then assumes a curve slightly oscillating around a fixed value in the middle area of the diagram, which indicates that the transient process has been completed.

In the time course of the oscillation amplitude Ao shown in FIG. 2, an embodiment of the method according to the invention was used in which a delay time t _{d designed in} such a way _is provided that the measurement period DT only starts after the transient process has ended. The extension of the delay time t _{d over time} is indicated by a double arrow in the diagram shown in FIG.

In addition, the diagram shown in FIG. 2 shows a tolerance range 3 which is defined by a reference amplitude R and a tolerance value a. The tolerance range 3 extends from a lower limit of the oscillation amplitude Ra to an upper limit of the oscillation amplitude R + a. The underlying method according to the invention provides that the counter-tool and the sonotrode come into contact when the oscillation amplitude leaves tolerance range 3 within the measurement period DT, _i.e. after the delay time t _d , and thus values greater than R + a or less than Ra assumes.

It can be seen that at the point of the time profile 1 of the oscillation amplitude Ao marked with the reference number 2, the oscillation amplitude Ao within the measurement period DT, which began after the delay time t _d , assumes a value outside of the tolerance range 3, after having previously had another Value within tolerance range 3. The associated point in time to is consequently determined by the point in time at which the oscillation amplitude Ao is outside the tolerance range 3 for the first time. The point in time to is now determined as the point in time at which the sonotrode and counter-tool came into contact.

In the embodiment of the invention on which the diagram shown in FIG. 2 is based, the ultrasonic vibration device is switched off after a delay time t _N as a reaction to the specific coming into contact of the counter tool and sonotrode, so that the vibration of the sonotrode ends. The follow-up time tN is also shown in FIG. 2 with a double arrow starting from the point in time t0 of the coming into contact. The method on which the curve 1 of the oscillation amplitude Ao is based provides that the oscillation amplitude is steadily reduced within the follow-up time t _N. When the delay time t _{N has} elapsed, the vibration of the sonotrode ends within a very short period of time, within which the vibration amplitude drops to the zero position of the vibration amplitude.

In summary: The present invention relates to a method for the detection of a coming into or out of contact with a sonotrode (4) which oscillates with a Frequency f and an oscillation amplitude Ao is offset, with a counter element (5). In order to provide a method by which a sonotrode coming into or out of contact with a counter-element can be detected particularly quickly and inexpensively, it is proposed according to the invention that the method has the following steps: chen course of the oscillation amplitude Ao (1) during a first measurement period DT, and (b) determining from the temporal course of the oscillation amplitude Ao (1) whether a coming into or out of contact occurred within the measuring period DT.

List of reference symbols

Time course of the oscillation amplitude

Place in the value range of the oscillation amplitude

Tolerance range

Sonotrode

Counter tool

increase

material

Reference amplitude

Tolerance value

t _d delay time

tN follow-up time

to time

t time

Ao vibration amplitude (amplitude of the vibration of the sonotrode)

Claims

Patent claims

1. A method for the detection of a coming into or out of contact of a sonotrode (4), which is set into oscillation with a frequency f and an oscillation amplitude Ao, with a counter element (5)

with the steps:

a) recording a time profile of the oscillation amplitude Ao (1) during a first measurement period DT,

b) Determining from the time profile of the oscillation amplitude Ao (1) whether stepping into or out of contact has occurred within the measurement period DT.

2. The method according to claim 1, characterized in that in step b) the sonotrode (4) comes into or out of contact with the counter-element (5) if the detected oscillation amplitude Ao is more than a predetermined reference amplitude R deviates from a predetermined tolerance value a or if the detected oscillation amplitude Ao lies outside a predetermined tolerance interval [T _min , T _max ].

3. The method according to claim 2, characterized in that before step a) during a second measurement period Dί a time profile of the oscillation amplitude Ao is recorded and from the detection during the second measurement period D Toler the reference amplitude and / or the tolerance interval are calculated.

4. The method according to claim 3, characterized in that i) a mean oscillation amplitude is calculated from the detection during the second measurement period Dί and the calculated mean oscillation amplitude is used in step b) as a predetermined reference amplitude

and / or that

ii) from the detection during the second measurement period Dί a minimum vibration amplitude Amin and a maximum amplitude A _ma x is determined and from the minimum vibration amplitude A _min and the maximum vibration amplitude Amax the tolerance interval T _mi n ^ amine and T _m ax ^ A _ma x is calculated.

5. The method according to any one of the preceding claims, characterized in that in step a) the sonotrode (4) is excited by a converter, wherein the converter is connected to a power generator and the current IE provided by the power generator and flowing through the converter ( Ϊ) is measured, the voltage U _E (t) applied by the power generator to the converter being measured, and from the measured voltage U _E (t) and from the measured current IE (Ϊ) the oscillation amplitude or a field quantity related to the oscillation amplitude of the electrical oscillation system consisting of the power generator and the converter is calculated.

6. The method according to any one of claims 2 to 5, characterized in that the process comprises the following further step:

c) Determination of a point in time to at which a contact was detected in step b) from the time curve of the oscillation amplitude (1), the point in time at which the oscillation amplitude within the measurement period DT first entered a tolerance range [T _min , T _max ] or [R- a, R + a] (3), or a point in time offset from this point in time by a predefined correction time is defined as point in time to of the coming into contact.

7. The method according to any one of the preceding claims, characterized in that in step a) a sampling rate for determining the time course of the oscillation amplitude of at least 2,000 samples / s, preferably of at least 5000 samples / s and particularly preferably of at least 15 000 samples / s is used.

8. The method according to any one of the preceding claims, characterized in that a counter-tool (5) is used as a counter-element, wherein a material to be processed (7) can be arranged between the sonotrode (4) and the counter-tool (5), and wherein the internal Contact between the sonotrode (4) and the counter tool (5) is detected.

9. Method for controlling an ultrasonic oscillating device,

which has a sonotrode (4) and a counter tool (5) and wherein the counter tool (5) is arranged opposite the sonotrode (4) during operation such that a material (7) for processing by the sonotrode (4) between the sonotrode ( 4) and counter tool (5) can be arranged,

with the steps:

A) Exciting the sonotrode (4) with an oscillation for a predetermined time duration t _d , then

B) performing the method according to claim 8, and

C) Stopping the excitation of the sonotrode (4) or moving the sonotrode (4) away from the counter-tool (5), if contact between the sonotrode (4) and the counter-tool (5) was detected in step B).

0. The method according to claim, characterized in that step C) is only carried out after a predefined follow-up time t _{N has been carried out} after a contact has been detected, a reduction in the oscillation amplitude preferably immediately after the contact has been detected is effected.