This application claims priority from European Patent Application No. 23171215.9, filed May 3, 2023, the disclosures of which are incorporated herein by reference in their entirety.
The present invention relates to the setting of rivets. More particularly, the present invention relates to a joining method for connecting at least two workpieces with a rivet adapted to reduce the risk of cracking in the rivet.
Self-piercing riveting (SPR) is a spot-joining technique in which a self-piercing rivet is driven, by a punch, into a layered workpiece supported on a die. The die is shaped so that as the rivet is driven into the workpiece towards the die, the material of the workpiece plastically deforms. This flow of workpiece material causes the annular tip of the rivet to flare outwards and remain encapsulated by an upset annulus of the workpiece material. The flared tip of the rivet interlocking with the upset annulus of the workpiece prevents removal of the rivet or separation of the layers of the workpiece.
Insertion of a rivet into the workpiece is performed using a drive unit with an actuator (for instance a linear actuator such as a hydraulic cylinder or an electric linear actuator) which is mounted on a support arm of a force reaction frame opposite a die (or anvil) mounted on another support arm of the force reaction frame. The linear actuator drives the punch and rivet towards a stationary workpiece and die. The large forces on a workpiece which occur when a rivet is set or during punching must be compensated by a counterforce. This is usually achieved by supporting the workpiece on a counterforce structure, which preferably substantially has the shape of a C and is therefore also usually designated as a C-frame.
For the precise setting of a rivet or accurate punching it is important to know how deeply a rivet or a die has penetrated into the workpiece. EP1228824A2 is directed to a method for riveting or punching dealing with this issue. More particularly, the deformation of the counterforce structure during a riveting or punching process is detected by a monitoring unit and a course of movement during the riveting or punching process is corrected as a function of the bending.
Experience shows that some rivets tend to crack during a setting step. More particularly, the rivet (or more particularly self-piercing rivet) may crack in the joining direction, notably when the bore of the self-piercing rivet is filled. These cracks then widen until the rivet reaches its final position. The tendency to crack formation depends, among other things, on the following factors: rivet length, rivet coating, hardness of the sheet to be riveted. Several developments have been made to overcome this issue. EP2631022A1 and EP3424611 for instance are directed to an improved die. US2020261966A1 is directed to an improved self-piercing rivet.
However, a need still exists to improve the setting of rivets, and notably to provide joining method which reduces the risk of damage in the fastener, like for instance the risk of cracking in the self-piercing rivet, notably without significant impact on cycle time and which works also for fasteners being mechanically coated. Examples of the present disclosure aim to address the aforementioned problems.
According to an aspect of the present disclosure there is a joining method for connecting at least two workpieces with a rivet comprising the steps of:
Such method with a controlled speed decrease and the definition of a predetermined maximal rivet setting speed which is not exceeded during the setting of the rivet allows to reduce the risk of cracks in the rivet. More particularly, it must be guaranteed, that the setting speed, from rivet contact point up to the end of the setting process is lower or equal to the defined setting speed. The defined maximum rivet length allows to keep the speed of the punch to a maximum up until it is reached, such that a faster punch speed is mostly used during the joining method. A faster punch speed is indeed advantageous for effective cycle times of the joining process. The speed reduction allows to avoid or sensibly decrease the cracks. The rivet speed is monitored to ensure an exact control of the process.
In an embodiment, the method further comprises the step of defining a predetermined maximal rivet length, and wherein the second punch speed is reached when the punch arrives at a position which corresponds to the predetermined maximal rivet length. The maximal rivet length is a point which is always reached before the rivet contact point and which can easily be indicated or defined by an operator. The maximal rivet length can be adjusted by an operator.
In an embodiment, the first punch speed is within a range of 150-1000 mm/s. This enables effective cycle times of the joining process.
In an embodiment, the second punch speed and/or the maximal predetermined rivet setting speed is within a range of 10-300 mm/s. In an embodiment, the maximal predetermined rivet setting speed is below 100 mm/s, or even below 50 mm/s. This allows to reduce the risks of crack, notably for self-piercing rivets having a mechanical coating.
In an embodiment, the drive unit decreases the punch speed such that the predetermined maximal rivet setting speed is reached when the predetermined maximal rivet length is reached. For instance, the speed decrease is constant such that a smooth transition is realized, the lower speed is reached only at the maximal rivet length or when the rivet first contacts the workpiece and the effective cycle time is not affected. Indeed, lower speed always increases the cycle time. The present method aims to have a minimal effect on the cycle time. The method can thus be used for a wide range of rivets having a length inferior to the pre-defined maximal rivet length.
In an embodiment, the second punch speed is correlated to the predetermined maximal rivet setting speed so that the predetermined maximal rivet setting speed is reached when the predetermined maximal rivet length is reached or when the rivet first contacts the workpiece.
In an embodiment, the deformation of the frame during the setting step is detected by a monitoring unit and a course of movement during the setting step is corrected as a function of the deformation. Thus, the exact position of the rivet with regard to the workpiece can be determine and therefore the rivet speed can be monitored and controlled. In an embodiment, the rivet speed could also be monitored without the knowledge of the workpiece position, but such monitoring is less accurate.
In an embodiment, a relative movement between the frame and clamping device is measured by a first sensor and a relative movement between the frame and the punch is measured by a second sensor. The two sensors can easily be implemented and allows to exactly determine the rivet speed.
In an embodiment, the first sensor and/or the second sensor is a linear path recorder, preferably a digital counter. For example, the digital counter counts stroke-shaped markings on a kind of ruler. This enables fast and accurate processing of the signals in a monitoring unit. In another embodiment, other systems like for instance laser can be used.
In an embodiment, the first and/or the second workpieces is a high strength steel workpiece. Components made of high strength steel are known to be difficult to join to each other or to other metals. Such high strength steel can, in some cases, have a tensile strength of at least 400 MPa. In another embodiment, the workpieces or at least one of the workpiece are/is made with thick (at least 3 mm) mild steels or hard aluminum alloys.
In another embodiment, three workpieces are joined, and the two upper layers are high strength steel workpieces.
In an embodiment, the predetermined maximal rivet setting speed is adjustable. Thus, depending on the rivet, the workpiece and the nature of the joint, the maximal rivet setting speed can be adjusted by an operator to optimize the cycle time while avoiding cracks.
Various other aspects and further examples are also described in the following detailed description and in the attached claims with reference to the accompanying drawings, in which:
The embodiments of the disclosure will be best understood by reference to the drawings, wherein the same reference signs designate identical or similar elements. It will be readily understood that the components of the disclosed embodiments, as generally described and illustrated in the figures herein, could be arranged and designed in a wide variety of different configurations. The steps of a method do not necessarily need to be executed in any specific order, or even sequentially, nor need the steps be executed only once, unless otherwise specified.
In some cases, well-known features, structures, or operations are not shown or described in detail. Furthermore, the described features, structures, or operations may be combined in any suitable manner in one or more embodiments. It will also be readily understood that the components of the embodiments, as generally described and illustrated in the figures herein, could be arranged and designed in a wide variety of different configurations.
The joining head further comprises a counterforce structure or frame 20. Typically, such frame 20 is a C-shaped frame composed of a solid material. A punch 22 displaceable on the frame 20 along a joining axis X is also provided. The punch 22 can be controlled by a drive unit 24 and a control device 26. The drive unit 24 may comprise an actuator to actuate the punch 22.
The joining head further comprises a die 28 that is mounted on the frame 20, and a clamping device 30. The die 28 is mounted at one end of the frame 20, wherein the clamping device 30 is mounted at the other end of the frame 20. The punch 22 is guided in the clamping device 30 by the drive unit 24. The clamping device 30 is adapted to be biased in the joining direction or in the direction of the die 28.
The joining arrangement 10 serves to connect a first workpiece 32 and a second workpiece 34 which, for example, can be designed as metal sheets, by a rivet 18. The setting tool 12 can also be used to join together more than two workpieces 32, 34. For instance, three workpieces are joined, and the two upper layers are high strength steel workpieces. The rivet 18 can be for example a self-piercing rivet 18 or punch rivet which can be a hollow or a semi-hollow punch rivet. The workpieces 32, 34 are for instance made of high strength steel. The control device 26 can be programmed such that a predetermined maximal rivet length can be entered. This predetermined maximal rivet length can be adjusted by an operator and corresponds to the maximal length of a rivet used for the joining method. The length of the rivet is the axial length and correspond to the length between the head of the rivet and the foot of the rivet. The predetermined maximal rivet length is given by an operator and can depend on the joining operations to be executed. For example, for joining operations in the automotive industry, a predetermined maximal rivet length of 8 mm can be used. The self-piercing rivet 18 can for instance be mechanically coated or galvanic coated for instance. The rivet 18 can be a self-piercing rivet as described in EP2631022A1 and EP3424611 for instance are directed to an improved die. US2020261966A1.
To set the rivet 18 in the workpieces 32, 34, the workpieces 32, 34 are placed on the die 28. The punch 22 is then moved by means of the drive unit 24 in the direction toward the die 28. In this case, the clamping device 30 first contacts a surface of the uppermost workpiece 32 and presses the workpieces 32, 34 together in the joining direction.
The punch 22 is driven in a first stage R1 at a first punch speed S1. The first punch speed S1 is for instance between 150 and 1000 mm/s. The first punch speed S1 can be constant or not. More particularly the first punch speed S1 can be raised to a particular maximal value, for instance 300 mm/s. The first punch speed S1 is commanded by the control device 26. The punch 22 is driven at the first punch speed S1 by the drive unit 24 and then the punch speed decreases until the punch reaches a position which corresponds to the given maximal rivet length. The punch speed slowly decreases from the first punch speed S1 to a second punch speed S2 such that as soon as the punch reaches the position corresponding to the predetermined maximal rivet length, it reaches the second punch speed S2. The punch speed reduction corresponds to a second stage R2. The second punch speed S2 is for instance a constant speed or sensibly constant speed. The second punch speed S2 is lower than the first punch speed S1.
During the motion of the punch 22 toward the die 28, the punch 22 contacts the head of the rivet and therefore drive the rivet into the workpiece arrangement to realize the connection. This stage corresponds to a third stage R3, during which the punch 22 drives the rivet 18 into the workpiece at the second punch speed and the rivet speed is monitored to ensure it does not exceed a predetermined maximal rivet setting speed. The predetermined maximal rivet setting speed is a data which is defined by the operator before the joining method in the control device. The predetermined maximal rivet setting speed and the second punch speed are correlated. The predetermined maximal rivet setting speed can be adjusted by an operator depending on the joining operation, the workpiece material, the rivet material, the rivet geometry, the die geometry, . . . . For instance, with a mechanically coated rivet, the predetermined maximal rivet setting speed is within a range of 10-300 mm/s. The predetermined maximal rivet setting speed can be below 100 mm/s, or even below 50 mm/s in a particular embodiment.
The predetermined maximal rivet length allows to ensure that the speed is decreased before or when the rivet contacts first the workpiece and therefore to determine when the punch speed needs to be decreased such that the lower punch speed to avoid the cracks on the rivet has a minimum impact on the cycle time.
In order to correctly monitor the rivet speed during the setting step, the setting tool comprises a monitoring unit 36 adapted to detect the deformation of the frame 20 during the setting process and a course of movement during the setting step can be corrected by the control device as a function of the deformation. Thus, the actual displacement of the punch 22 and/or the rivet 18 can be determined, and the actual rivet speed correctly monitored. A first sensor 38 measures the relative movement between clamping device 30 and frame 20. This sensor is preferably a linear path recorder consisting of a kind of ruler which makes the same movement as the clamping device and a counter which is fixed to the frame and counts markings on the ruler going past it. A second sensor 40 measures the relative movement between frame and punch.
The first sensor 38 and the second sensor 40 are connected to the monitoring unit 36, which can thereby detect the bending of the frame during action of force by the punch 22 and the clamping device 30 on the workpiece 32, 34. With the knowledge of the bending of the frame 20 detected in this way the movement of the punch can be adjusted in such a way that a constant penetration depth of the rivets is always ensured. More particularly, the position of the rivet with regard to the workpiece can always be measured. This allows to determine the exact punch position, but also the exact rivet speed and to monitor correctly that the rivet speed does not exceed the predetermined maximal rivet setting speed. The course of movement can thus be corrected by the control device during the riveting or setting or joining process as a function of the bending.
In
Joining arrangement 10, setting tool 12, robot 14, feeder hose 16, rivet 18, frame 20, punch 22, joining axis X, drive unit 24, control device 26, die 28, clamping device 30, first workpiece 32, second workpiece 34, first punch speed S1, second punch speed S2 first stage R1, second stage R2, third stage R3, monitoring unit 36, first sensor 38, and second sensor 40.
Number | Date | Country | Kind |
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23171215.9 | May 2023 | EP | regional |