DE102014202598A1 - Method for the qualitative analysis of compounds of joining partners - Google Patents

Abstract

The invention relates to a method for the qualitative analysis of compounds of at least one first joining partner (6) and a second joining partner (7), which are formed by at least one joining region (2) formed by deformation and bonding (8) or by thermal joining and bonding (8) ) are interconnected, wherein at least the first joining partner (6) is made of a fiber composite plastic. The method comprises the steps:
Defining a joining influence area (3) around the joining area (2), in which the connection of the joining partners (6, 7) is not analyzed, and
- Performing an analysis of the connection of the joining partners (6, 7) exclusively in a test area (4), which lies exclusively outside the joint influence area (3).

Description

The present invention relates to a method for the qualitative analysis of compounds of at least one first joining partner and a second joining partner. This method is used in particular in the vehicle sector. Furthermore, the invention relates to a device for carrying out the method and a computer program product for carrying out this method.

Due to the lightweight design of the workpieces, which is currently required in vehicle construction, fiber composite plastics are increasingly being used. In order to meet the high demands on the stability and resilience of these workpieces, fiber composite plastics are often joined by means of hybrid bonding techniques, and in addition to a bonding in particular to form non-positive and / or positive connections. These joining techniques or bonding techniques lead to imperfections, such as delamination, cracking, fiber defects and the like in the joint area of the joining partners. Since even the smallest imperfections can lead to considerable loss of stability of the workpieces, which also contribute to safety-relevant aspects in vehicle construction, time-consuming and expensive tests, and in particular macrosections, are carried out by means of which a complete qualitative analysis of the joints of the joining partners takes place. The disadvantage of this is the high time and cost factor, as well as a difficult assessment of the impact of Fügeimperfektionen.

Based on this prior art, it is therefore an object of the present invention to provide a method which allows a simple, reliable and time and cost-saving qualitative analysis of compounds of joining partners. In addition, it is an object of the invention to provide a device for carrying out the method, which is easy to operate without high technical background knowledge and allows a reliable assessment of the compounds of the joining partners. Furthermore, it is an object of the invention to specify a computer program product for carrying out the method and a use of the method.

• – Definieren eines Fügeeinflussbereichs um den Fügebereich, in dem die Verbindung der Fügepartner nicht analysiert wird, und
• – Durchführen einer Analyse der Verbindung der Fügepartner ausschließlich in einem Prüfbereich, der ausschließlich außerhalb des Fügeeinflussbereichs liegt.

The object is achieved by a method having the features of the main claim. Thus, the object is achieved by a method for the qualitative analysis of compounds of at least one first joining partner and a second joining partner, which are interconnected by at least one joining region formed by deformation and bonding or by thermal joining and bonding, wherein at least the first joining partner from a Fiber composite plastic is made. Surprisingly, it has been found that for hybrid compounds, ie those which are formed in addition to bonding by forming or thermal joining, Fügeimperfektionen have no significant adverse effects on the stability and mechanical strength of the compounds of the workpieces. In order to reduce the effort, and thus also the time and costs of the analysis of the hybrid compounds, the method according to the invention therefore comprises the steps:

• Defining a joining influence area around the joining area, in which the connection of the joining partners is not analyzed, and
• - Performing an analysis of the connection of the joining partners only in a test area that lies exclusively outside the joint influence range.

The joining area is considered to be the forming area or thermal joining area in which the joining partners are connected to one another. If the joining next to the bond by forming z. Example by means of a joining element, such as a nail, a screw or a rivet, the joining region is given by the geometry of the joining element. In the case of thermal joining in addition to a bond, the joint area, as for example for a spot weld, may also be only one joining point. In this case, the area around the joining area, in which joining imperfections have no negative influence on the required workpiece properties, is regarded as joining influence area. The joining influence range results from the fact that damage directly to the joining region generated by deformation or thermal joining due to the adhesive cohesion of the joining partners by the bond can not affect. Fügeimperfektionen in the joint influence range can therefore be declared harmless and therefore permissible. An analysis of the connection of the joining partners is therefore carried out according to the invention exclusively in a lying around the joining influence range test area. Joint imperfections in this test area can be identified and classified as harmful, depending on the degree of imperfection. An analysis which avoids the analysis of the connection of the joining partners in the joining influence range thus leads to a very reliable statement about the quality of the connection while at the same time saving time and costs.

The dependent claims have advantageous developments of the invention to the content.

An advantageous development of the method according to the invention provides that the joining influence area extends with a width around the joining area which is at most 0.75 times, preferably at most 0.6 times, and particularly preferably at most 0.5 times, one in cross section smallest diameter of the joining area. In other words, the joining influence region defines a surface lying around the joining region and extending essentially radially around the joining region, with a certain diameter seen from the center of the joining region. According to the invention, "in cross-section" means parallel to the direction of lamination the joining partner, ie in the direction of the bond. In the simplest case, the joining area is cylindrical. The joining influence area is thus an area which is defined by an inner circle which represents the outer edge of the joining area and an outer circle which separates the checking area lying around the joining influence area from the joining influence area. Depending on the width with which the joining influence region extends around the joining region, the closer the test region lies to the joining region and the more reliably an assessment of the stability of the connection of the joining partners can be made. With a width that is at most 0.5 times the smallest diameter of the joint area (viewed in cross-section), joint imperfections can be taken into account particularly reliably in the qualitative assessment of the joints.

In particular, the deformation using a joining element and in particular by nailing, screws, such. B. flow hole screws, rivets, such. As blind rivets, semi-punched rivets and solid punch rivets or performed by high speed studs, since in this way very durable and mechanically stable connections can be formed. The method is thus particularly easy to apply because the joint influence range can be easily defined due to the known geometry of the joining element. Fügeimperfektionen can thus be very reliably determined.

Further advantageously, the forming is carried out using a joining element and in particular by riveting with a rivet, wherein the joint influence region is selected so that it extends around the joining region with a diameter, starting from the center of the joining element, the maximum of 2.4 times , preferably at most 2.2 times, and more preferably at most 2 times the diameter of the joining element. The expansion of the joining area with a maximum diameter of 2.4 times the diameter of the joining element ensures that all joining imperfections that can not adversely affect the stability and mechanical strength of the workpiece are excluded from the analysis. A smaller diameter of 2.2 times or in particular 2.0 times the diameter of the joining element ensures particularly well that all imperfections resulting from the joining of the joining partners by forming or thermal joining are declared admissible.

Due to the very good connection stability and at the same time good estimability of joining imperfections, the thermal joining is preferably carried out by welding and, in particular, by friction element welding.

For time and cost reasons, the analysis of the connection of the joining partners in the test area is advantageously carried out by a destructive or a non-destructive test, in particular by means of optical methods or by means of ultrasonic methods. Optical methods have the advantage that they require a particularly low technical effort, while ultrasonic methods can be carried out non-destructive, so that very little rejects produced.

For further simplification and temporal streamlining of the method according to the invention, the test region is selected such that it extends with a width around the joint influence region which is at least 0.5 times, preferably at least 1.1 times, and particularly preferably at least 1, 5 times the respective width of the joining influence area around the joining area. Thus, all significant parts of the connection of the joining partners fall into the test area and characterized by Fügeimperfektionen workpieces can be quickly declared reliably without high cost as inadmissible.

A further advantageous embodiment provides that at least the second joining partner is embossed before joining with the first joining partner and forms a bead. For this purpose, the second joining partner is preferably formed from a metallic material. A bead is a substantially annular recess arranged around the joint area. The area of the bead thus comprises no adhesive. The joining influence area can thus be defined directly as the area of the bead, since in this area there is no force acting on the joint imperfections of the workpiece, which can adversely affect the stability of the workpiece. By way of example, the bead has a depth of about 1.5 mm. Thus, in the joining influence region, a gap about 1.5 mm wide, into which no adhesive passes, is produced.

Also according to the invention, a device for carrying out the above-described method is disclosed, which comprises an imaging device which is set up to define a joining influence region on the basis of data on the joining region of the first joining partner and of the second joining partner and exclusively a pictorial representation of the Play test area of a workpiece. An exemplary imaging device is a microscope, which comprises an input device, via which data on the joining region, for example the diameter thereof, can be made after positioning the workpiece to be examined under the microscope. The microscope determines the joining influence range on the basis of this data. In the microscope, only the test area lying exclusively outside the joint influence range is then focused and / or illuminated so that a qualitative analysis of the connection of the binding partners and assessment of the quality of the workpiece can be made in a short time in a cost-saving manner without much background knowledge.

Furthermore, the invention relates to a use of the method described above. The method for the qualitative analysis of compounds, ie hybrid compounds, is advantageously used in the manufacture of vehicles. Here, the method described above offers advantages with regard to time and cost aspects in the manufacture of vehicles. Hybrid compounds are those which are formed in addition to a bond by forming or thermal joining.

Finally, the invention relates to a computer program product. The computer program product in particular comprises a program code stored on a machine-readable storage medium for carrying out the method described above. For this purpose, the computer program product must run on a computer or, in particular, on another computing unit, such as an integrated control unit.

Further details, features and advantages of the invention will become apparent from the following description and the figures. Show it:

1 a schematic illustration of a cross section through a workpiece, which is analyzed by the method according to the invention and

2 a schematic illustration of a longitudinal section through a workpiece, which is analyzed by the method according to the invention.

The present invention will be explained in detail with reference to an embodiment. In the figures, only the aspects of the method according to the invention which are of interest here are shown, all other aspects have been omitted for the sake of clarity. In the figures, like reference numerals indicate like elements.

1 schematically illustrates a cross section through a workpiece, which is analyzed by the method according to the invention. The workpiece is formed from at least a first joining partner and a second joining partner, wherein at least the first joining partner is made of a fiber composite plastic. The joining partners are connected to one another by a hybrid connection, that is to say by forming and bonding or by thermal joining and bonding. The region formed by deformation or by thermal joining becomes a joining region 2 Are defined. Example becomes in 1 the joining area 2 through a joining element 5 formed, z. As a nail, a screw or a rivet. The dimension of the joining element 5 sets the forming area and thus the joining area 2 dar. The joining area 2 has a center M around which it extends with a diameter D1.

According to the method according to the invention, a joining influence region now becomes 3 defined, which is about the joining area 2 extends. The joining influence area 3 extends preferably with a width A1 to the joining area 2 , the maximum of 0.5 times the smallest diameter D1 of the joining area 2 is. It should be noted that, since the diameter D1 of the joint area 2 in 1 is circular, there is only one diameter D1, which thus also the smallest diameter of the joining area 2 represents. In the joining influence area 3 the connection of the joining partners is not analyzed, since here Fügeimperfektionen due to the bond is not detrimental to the workpiece 1 impact.

Further preferably, the joining influence region extends 3 around the joining area 2 with a diameter D2, starting from the center M of the joining element 5 a maximum of 2 times the diameter D1 of the joining element 5 is.

It is an analysis of the connection of the joining partners exclusively in a test area 4 performed exclusively outside the joint of influence 3 lies. Also the test area 4 extends into 1 exemplarily radially around the joining influence region 3 , Preferably, the test area 4 is chosen so that it is with a width A2 to the joining influence area 3 extends, which is at least 1.5 times the respective width A2 of the joining influence region 3 around the joining area 2 is.

The analysis of the connection of the joining partners in the test area 4 can be done by a destructive test or by a nondestructive test. It is also possible to combine both test methods.

The inventive device would according to 1 z. B. only the area 4 depicted, so that a qualitative analysis of the connection of the joining partners only on essential parts of the workpiece 1 in which joint imperfections such as delamination, cracks, indentations, voids, and the like, adversely affect the quality of the workpiece 1 to lead. Joint imperfections in the test area 4 can therefore easily be considered inadmissible.

2 is a schematic longitudinal section through the workpiece 1 out 1 , which is analyzed by the method according to the invention. In 2 is the through the joining element 5 achieved reshaping very well. Thus, the first joining partner 6 and the second joining partner 7 not just by gluing 8th between the layers of the joining partners 6 . 7 , but also through the by the joining element 5 , shown here by way of example in the form of a rivet, achieved reshaping.

Again, only a qualitative analysis of the test area is done here 4 in the workpiece 1 , Due to the multilayer structure of the workpiece 1 , the analysis of the test area is carried out 4 preferably by means of an ultrasonic method.

The foregoing description of the present invention is for illustrative purposes only, and not for the purpose of limiting the invention. Various changes and modifications are possible within the scope of the invention without departing from the scope of the invention and its equivalents.

LIST OF REFERENCE NUMBERS

1

workpiece

2

joining area

3

Add Sphere of Influence

4

inspection

5

joining element

6

first joint partner

7

second joint partner

8th

splice

A1

Width at which the joining influence area extends around the joining area

A2

Width with which the test area extends around the joining influence area

M

Center of the joining element

D1

Diameter of the joining area

D2

Diameter of the joining influence area

Claims (11)

Method for the qualitative analysis of compounds of at least one first joining partner ( 6 ) and a second joint partner ( 7 ) by at least one by forming and gluing ( 8th ) or by thermal joining and gluing ( 8th ) joining area ( 2 ), at least the first joining partner ( 6 ) is made of a fiber composite plastic, comprising the steps: - defining a joining influence region ( 3 ) around the joining area ( 2 ), in which the connection of the joint partners ( 6 . 7 ) is not analyzed, and - carrying out an analysis of the connection of the joint partners ( 6 . 7 ) exclusively in a test area ( 4 ), which is exclusively outside the joint influence range ( 3 ) lies. Method according to claim 1, characterized in that the joint influence region ( 3 ) with a width (A1) around the joining area ( 2 ), which is at most 0.75 times, preferably at most 0.6 times, and more preferably at most 0.5 times, a diameter of the joining region (D1) which is the smallest in cross section. A method according to claim 1 or 2, characterized in that the forming using a joining element ( 5 ) and in particular by nailing, screws, such. B. flow hole screws, rivets, such. B. blind rivets, semi-punched rivets, solid punch rivets or by high-speed bolt set is executed. Method according to one of the preceding claims, characterized in that the forming using a joining element ( 5 ) and in particular by riveting with a rivet, wherein the joining influence area ( 3 ) is selected so that it extends around the joining region ( 2 ) with a diameter (D2), starting from the center (M) of the joining element ( 5 ), the maximum of 2.4 times, preferably at most 2.2 times, and more preferably at most twice the diameter (D1) of the joining element ( 5 ) is. Method according to one of the preceding claims, characterized in that the thermal joining is carried out by welding, and including in particular by friction element welding. Method according to one of the preceding claims, characterized in that the analysis of the compound of the joining partners ( 6 . 7 ) in the test area ( 4 ) is performed by a destructive or a non-destructive test, in particular by optical methods or by ultrasonic methods. Method according to one of the preceding claims, characterized in that the test area ( 4 ) is selected so that it has a width (A2) around the joining influence region ( 3 ) which is at least 0.5 times, preferably at least 1.1 times, and most preferably at least 1.5 times times the respective width (A1) of the joint influence region ( 3 ) around the joining area ( 2 ) is. Method according to one of the preceding claims, characterized in that at least the second joining partner ( 7 ) is embossed before joining with the first joining partner and forms a bead. Device for carrying out the method according to one of the preceding claims, comprising an apparatus for imaging, which is set up on the basis of data on the joining area ( 2 ) of the first joining partner ( 6 ) and the second joining partner ( 7 ) a joining influence area ( 3 ) and only a pictorial representation of the test area ( 4 ) play. Use of the method according to one of claims 1 to 8 for evaluating hybrid compounds used in the manufacture of vehicles, preferably motor vehicles. Computer program product for carrying out the method according to one of claims 1 to 8, when the computer program product runs on a computer.

Images