DE4317621C1 - Processing a component by means of ultrasound - Google Patents

Abstract

Appts. (1) for processing a component of joining two components (3,4) by means of ultrasound incorporates an ultrasonic welding unit (5) with a converter (6) and a sonotrode (7).The appts. is provided with a position measuring unit (11) which determines the distance of the sonotrode from the component (3) and is connected to the control unit of the ultrasound generator.The welding parameters for the sonotrode (7) are set by the ultrasound generator (via the converter (6) dependent on the signals from the control unit supplied with data from the position measuring unit (11).The position measuring unit (11) is contactless measuring system (e.g. an optical or acoustic measuring system). Alternatively, it is a contacting system such as, for example, a line potentiometer or a mechanical probe.The appts. (1) is a standard press, a special machine, a hand-held gun, a robot-operated tool, etc..The control unit (which incorporates a personal computer) produces signals for welding parameter such as welding energy, duration, path, feed rate, amplitude, frequency and/or beginning and end of sound application.

Description

The invention relates to a device for processing a Component or for connecting two components by means of Ultrasound, with an ultrasound generator and one Ultrasound system, the ultrasound system being a Ultrasonic welding device with a converter and one Has sonotrode. The invention also relates to a Method for connecting two components using ultrasound, in which an ultrasound generator has a sonotrode over a Converter vibrated.  

The processing of a component or the connection of Components using ultrasound are used in modern times Manufacturing processes are increasingly used. By means of this Procedures include point, seam and Butt welds achieved by the energy of Concentrated ultrasonic vibrations and thereby the Plasticized weld and the materials together get connected. The vibrations are over the sonotrode transmitted perpendicular to the clamping force of the components the welding point. This will be oxide skins torn open, roughness leveled and a weld of the two components. With the welding process mainly thin sheets and wires with thicker ones Underlays welded, whereby metals, such as aluminum, Copper, brass, silver, gold, titanium, tantalum and molybdenum, and in particular thermoplastics be connected to each other. The ultrasonic welding has the advantage that relatively large components with relative small components easily and safely with each other are connectable.

It is essential for high quality welded joints required that always the same working conditions for the Ultrasonic welding device are available. In addition, should neither the components to be joined together nor the The welding device may be damaged. Usually will the individual welding parameters are determined empirically and before  Start of welding the components on the ultrasonic generator or set on the ultrasound device. Changes however, for example the thickness of the component, so increases in the Regulate the contact pressure, which is an increase in temperature Welding point entails.

EP 421 019 A1 and DE 39 21 653 A1 disclose that the lifting speed of the pneumatic Feeding device of the sonotrode depending on the Contact pressure is controlled. It is also known that the Triggering and termination of sound emission depending of the stroke or the contact pressure or into the workpiece introduced energy is controlled. With other systems the control of the joining process is force-controlled or temperature controlled. With these systems, however, must always checks the welding point during the welding operation after welding, the individual Spot welds subjected to random checks to find mis-welds and more Avoid mis welds by the ultrasonic generator and / or the welding devices reset or be adjusted. This approach is not only cumbersome and time-consuming, it does not guarantee any consistent quality when welding two Components.  

EP 208 310 A1 describes a method and a device to regulate the course of the process in ultrasonic welding of Workpieces become known for the process variable for regulation the welding time, welding energy or Welding performance or the deformation of the welded Workpieces can be recorded as parameters. Especially with the Determining the deformation of the work pieces can be extreme Fluctuations in the quality of the welds occur because the whole control system is extremely sluggish.

Starting from a state of the art according to EP 208 310 A1 is therefore the object of the invention, a Device and a method of the type mentioned to develop in such a way that with these Fluctuations in the quality of the weld between two components be significantly reduced.

This task is the beginning of a device mentioned type according to the invention solved in that the Provide the ultrasound system with a position measuring unit which is the position, especially the distance of the Sonotrode detected in relation to the component, and that the Position measuring unit with an ultrasound generator driving control unit is connected.

By attaching a position measuring unit to the Ultrasound system can determine the exact position of the sonotrode  Example related to the component, i. H. the distance of the Sonotrode of the component can be detected. From this distance or from the position with respect to the component Information on controlling the ultrasound generator be obtained, thereby reducing the quality of the welded joint can be improved. So z. B. be determined exactly when the sonotrode tip touches the component and when the desired depth of penetration or the desired feed is reached. In this way, e.g. B. the beginning of Sound emission exactly defined and z. B. the feed of Fast to slow speed. When reached the feed end is then the sound output with or without a certain hold time ended. That way is one ensures high quality of the welded joint and the Welding device can respond to changes in dimensions the components, e.g. B. on changes in thickness, etc., immediately react. Changes in the dimensions of the components thus do not cause quality changes, in particular Loss of quality of the welded joint. The control of the Ultrasound generator on the distance of the sonotrode from Component also has the advantage that the service life of Ultrasonic welding device can be increased in particular, the sonotrode may break due to Overloading, incorrect delivery, etc. can be avoided. In a preferred embodiment, that the position measuring unit as a non-contact measuring system,  e.g. B. as an optical or acoustic measuring system, such as Laser triangulator or the like is formed. Non-contact measuring systems have the advantage that the welding process itself does not affect the measuring process and therefore a continuous measurement can take place. In addition, non-contact measuring systems have the advantage that they work wear-free.

In another embodiment it is provided that the position measuring unit as a touching measuring system, e.g. B. as Length potentiometer, mechanical button or the like, is trained. This measuring system has the advantage that it has a simple structure and is relatively inexpensive.

In a further training it is provided that the Ultrasonic system as a standard press, special machine, Hand gun, robot tool or the like is formed is. The ultrasound system is not special System type limited, but can be in any joining station a production line can be provided in the components connected to one another by means of ultrasound, in particular be welded.

A particularly simple processing of the measured values in the Control unit is achieved in that this with a Data processing system is connected, in particular a Has personal computer (PC). Using this PC's can  Position data are compared with target values and at a deviation can corresponding control signals to the Ultrasound generator are issued. Furthermore, the Position values are saved to them for later Comparison with other current position measurements to be able to use.

In a further training it is provided that the Control unit with a timer and / or Load cell is connected. Via the timer advantageously determines the speed of the sonotrode become. Now the sonotrode is directed towards a component move and the sonotrode sits on the component, then the feed rate of the sonotrode changes what is instantaneously detected via the control unit and corresponding control data to the ultrasound generator be issued. Another embodiment provides that can be detected via a load cell when the Sonotrode sits on the component.

The above task is carried out in a method of initially mentioned type solved according to the invention in that the positions, especially the distance of the sonotrode in measured with respect to the component and the measured value of a Control unit fed and in the control unit too Control signals is processed, and that the  Ultrasound generator depending on these control signals Sets welding parameters for the sonotrode.

Depending on the position of the sonotrode, e.g. B. the distance the sonotrode of the component, so z. B. the Feed rate of the sonotrode changed that Sound emission switched on or off etc. and thereby acted specifically on the welded joint.

The fact that next to the position of the sonotrode in relation to the component measured over time and / or the contact pressure the sonotrode is detected, z. B. by determination the speed of the sonotrode further control data are generated, which also influence the Weld connection can be made.

The control unit preferably provides the welding parameters Using one or more maps. Maps are e.g. B. already from modern ignition systems for motor vehicles known where also several vehicle data to each other in Relationship set and the corresponding ignition parameters be determined. Based on the map (s) you can not just individual welding parameters such as amplitude or Contact pressure, can be set, but it can be Large number of welding parameters at the same time or can be changed one after the other. So z. B. the Welding energy, the welding time, the holding time, the  Welding path, the stroke, the stroke speed, the Contact pressure, the feed rate, the amplitude, the Frequency, the start or end of sound emission, etc. be managed. This list is not intended to be exhaustive be understood.

The measured values with a tolerance field are preferred compared. In this way, the goodness of the Welded connection kept within certain tolerances become. If the measured values deviate from the tolerance range the control signals for the welding parameters are like this changed that the measured values back into the tolerance field hike. Through this regulation, what is done via maps optimal quality assurance is achieved.

An advantageous use of the invention Device and the inventive method is in Welding rivets, spot welding or embedding Seen metal parts.

Further advantages, features and details of the invention result from the following description, in which particularly preferred with reference to the drawing Embodiments are described in detail. Here is in the drawing the structure of the invention Device only reproduced in principle. Show it:  

Fig. 1 is a side view of an ultrasonic system;

Fig. 2, the horn tip with another unit;

Fig. 3, the sonotrode tip having a third measuring unit; and

Fig. 4 is a diagram showing the distance of the sonotrode with respect to the component over time.

In FIG. 1, an ultrasound system is denoted overall by 1 , which can be designed, for example, as a welding press, multi-head machine, robot tool, hand gun or the like. This ultrasound system 1 is shown only schematically in the drawing, and only the elements necessary for understanding the invention are shown. The ultrasound system 1 is connected to a control unit, not shown, such as an ultrasound generator.

The ultrasound system 1 is arranged above a sound reflector 2, which is only shown schematically, on which the workpieces or components 3 and 4 to be connected rest and are optionally clamped. In the exemplary embodiment shown in FIG. 1, the component 4 is designed as a rivet which penetrates the component 3 and is provided for welding. Above components 3 and 4 there is an ultrasonic welding device 5 , which is provided with a converter 6 at its upper end and with a sonotrode 7 at its lower end. A booster 8 can be provided between the converter 6 and the sonotrode 7 . The ultrasonic welding device 5 can be raised or lowered onto the components 3 and 4 via a linear drive 9 , so that it rests on them with a certain contact pressure.

A position measuring unit 11 is provided in the immediate vicinity of the sonotrode tip 10 and measures the position of the sonotrode 7 in relation to the component 3 without contact. The position measuring unit is used as an optical measuring system, e.g. B. executed as a laser triangulator. With this position measuring unit, a characteristic curve can be determined as it is e.g. B. is shown in Fig. 4.

The characteristic curve 12 shown in FIG. 4 represents the distance a of the position measuring unit 11 from the surface of the component 3 over the time t. At the operating point 13 at the time t = 0, the sonotrode 7 is moved via the linear drive 9 in the direction of the component 3 postponed. The distance of the sonotrode changes according to the branch 14 of the characteristic curve 12 to the break point 15 , where the sonotrode tip 10 is seated on the surface of the component 4 . The contact pressure of the linear drive 9 is such that it is not sufficient to move the sonotrode further. The sonotrode 7 thus remains in this position by contact with the component 4 . After a short period of time, the ultrasound delivery is switched on at operating point 16 and the contact pressure is increased if necessary. Due to material softening and possibly due to the higher contact pressure, the distance between the sonotrode tip 10 and the component 3 is reduced according to the branch 17 of the characteristic curve 12 . At working point 18 , the tip of the sonotrode has reached its maximum feed and is stopped. The sonotrode tip remains at this distance for a certain time and is moved back to the starting position from the working point 19 to the working point 20 .

In FIG. 4, it is seen that the branch 17 of the characteristic curve 12, a tolerance zone 21 passes. As long as the branch 17 does not laterally break out of the tolerance zone 21 , the welding process takes place within fixed tolerance values. However, if the sound output is too great or the contact pressure of the sonotrode 7 on the component 4 is too high, the characteristic curve runs out of the tolerance field 21 , which is indicated by the branch 22 . The same applies correspondingly if the sound emission is too low or if the contact pressure is too low, where the characteristic curve runs out of the tolerance field 21 , as indicated by the branch 23 . If this is the case, the course of the characteristic curve 12 is corrected by changing the parameters for the ultrasonic welding device 5 accordingly, so that it remains within the tolerance range 21 .

The speed of the sonotrode 7 can be determined by a time recording in addition to the measurement of the position of the sonotrode tip with respect to the components 3 or 4 . Furthermore, the contact pressure can be determined in parallel via a load cell and processed for control.

Figs. 2 and 3 show embodiments of the position measurement unit 11, which is executed in the FIG. 2 as Längenpotentiometer or in Fig. 3 as a mechanical switch. If, for example, several push buttons are arranged according to FIG. 3, different operating points can be scanned using these push buttons.

Claims (16)

1. Device for processing a component or for connecting two components ( 3 and 4 ) by means of ultrasound with an ultrasound generator and an ultrasound system ( 1 ), the ultrasound system ( 1 ) being an ultrasound welding device ( 5 ) with a converter ( 6 ) and a sonotrode ( 7 ), characterized in that the ultrasound system ( 1 ) is provided with a position measuring unit ( 11 ) which determines the position, in particular the distance (a), of the sonotrode ( 7 ) with respect to the component ( 3 ), and that the position measuring unit ( 11 ) is connected to a control unit which controls the ultrasound generator. 2. Device according to claim 1, characterized in that the position measuring unit ( 11 ) is designed as a contactless measuring system, for example as an optical or acoustic measuring system, such as a laser triangulator. 3. Apparatus according to claim 1, characterized in that the position measuring unit ( 11 ) is designed as a contact measuring system, for example as a length potentiometer, mechanical button or the like. 4. Device according to one of the preceding claims, characterized in that the ultrasound system ( 1 ) is designed as a standard press, special machine, hand gun, robot tool. 5. Device according to one of the preceding claims, characterized in that the control unit is a PC having. 6. Device according to one of the preceding claims, characterized in that the control unit with a Timepiece and / or a load cell is connected. 7. The device according to claim 6, characterized in that the speed of the sonotrode ( 7 ) can be detected by the position measuring unit ( 11 ) and the timing element. 8. A method for connecting two components ( 3 and 4 ) by means of ultrasound, in particular with a device according to one of the preceding claims, in which an ultrasound generator vibrates a sonotrode ( 7 ) via a converter ( 6 ), characterized in that the position , in particular the distance (a), the sonotrode ( 7 ) is measured with respect to the component ( 3 ) and the measured value is fed to a control unit and processed into control signals in the control unit, and that the ultrasound generator uses these control signals to determine the welding parameters for the sonotrode ( 7 ) sets. 9. The method according to claim 8, characterized in that the control unit the control signals for the Welding parameters using one or more Maps determined. 10. The method according to claim 8 or 9, characterized characterized in that the control unit receives the control signals for the welding parameters, such as welding energy, Welding time, holding time, welding distance, contact pressure, Feed rate, amplitude, frequency and / or Start and end of sound emission determined. 11. The method according to any one of claims 8 to 10, characterized in that in addition to the position of the sonotrode ( 7 ) with respect to the component ( 3 ), the timing and / or the contact pressure of the sonotrode ( 7 ) is measured. 12. The method according to any one of claims 8 to 11, characterized in that the speed of the sonotrode ( 7 ) is measured. 13. The method according to any one of claims 8 to 12, characterized characterized in that the welding process is controlled or is regulated. 14. The method according to any one of claims 8 to 13, characterized characterized in that the measured values with a tolerance field be compared. 15. The method according to claim 14, characterized in that if the measured values deviate from the tolerance range, the Control signals for the welding parameters can be changed. 16. Use of a device according to claims 1 to 7 and / or a method according to claims 8 to 15 for welding rivets, spot welding, Embedding of metal parts, web welding, forming, Welding of joining surfaces.