WO2024008838A1 - Joining element made of shape memory steel and method for producing a releasable joining connection - Google Patents

Abstract

The present invention relates to a joining element (1) for producing a releasable joining connection, wherein the joining element (1) consists at least partially of a shape memory steel and in order to produce a joining connection with a joining partner (2, 2A, 2B) can be deformed, starting from a basic state, into a joining state through the application of force, and in order to undo the joining connection can be deformed at least partially from the joining state back into a disassembly state through the application of heat. Furthermore, the present invention relates to a system (5) for producing a releasable joining connection and to a method for producing and releasing a joining connection.

Description

Joining element made of shape memory steel and method for producing a detachable joining connection

Technical area

The present invention relates to a joining element made of shape memory steel for producing a releasable joining connection and a method for producing and releasing a joining connection using such a joining element.

In many areas of technology it is necessary to connect two components together. Classic mechanical joining methods include riveting, crimping or connecting using locking ring bolts to mechanically reliably connect components to one another. Such processes are known for their irreversibility, since the joining partners used in them are plastically deformed by pressing processes and thus an irreversible joining process takes place. This prevents both the simple, non-destructive dismantling of such joints and the easy recyclability of the components and joining partners.

Recently, the focus has been on economic aspects of dismantling and the reusability of raw materials. In other words, recyclability and dismantling must not only be economical for products with very valuable raw materials. The topic has already been examined in various approaches in research. Some ideas are based on integrating actuators made of shape memory materials into products. What the shape memory materials have in common is that when a certain switching signal is exceeded or fallen below, they switch from a first solid-state phase to a second solid-state phase that is different from the first. A previously plastically deformed shape memory material can be brought into its original shape by a switching signal, such as when a switching temperature is exceeded. Thus, activation can take place, triggered from outside, in order to return a component to a state, for example by heating, which enables easier disassembly.

Description of the prior art

Joining methods with detachable joining elements, which facilitate the dismantling of the components provided, are known in the prior art. Patent document DE 101 09222 shows a joining element for connecting two objects, the joining element partly consisting of a shape memory alloy and having a first shape in the initial state and a second shape that mechanically connects the objects in the final assembly position. By activating the shape memory alloy through sufficient cooling to the switching temperature, the joining element can be deformed back to its original state become. This makes dismantling easier after the joining element has been used.

However, the joining element described above also has some disadvantages: The classic shape memory alloys are thermoelastic. Thermoelasticity describes the property of a material to be reversible between two solid phases and to be able to change the solid phase only by changing the temperature. The phase that is present in the cold state is called martensite and the warm phase is called austenite. Classically, the shape memory alloy in martensite has a twin structure (imaginable in two dimensions like a fan). If the shape memory alloy is deformed, this twin structure is detwinned (smoothed out). Heating converts the shape memory alloy into austenite and reverses the stretching and macroscopic deformation. If the alloy is then cooled, twinned martensite forms again and the cycle closes. There is only a small difference in the temperature transition range of classic shape memory alloys, the so-called hysteresis. This describes the temperature difference between the martensite to austenite and the austenite to martensite transformation. This is a few degrees Celsius (in the one to two-digit Kelvin range).

Classic shape memory alloys have some disadvantages when used in joints. The biggest disadvantage is the very high costs resulting from the high material costs and the high production costs due to the complex and time-consuming processing. These costs alone make the use of large quantities of shape memory alloys uneconomical. Furthermore, the conversion temperatures are in ranges that are unsuitable for most joining elements. Adjusting these temperatures to suitable ranges is sometimes possible, but involves larger material and/or process costs. Another disadvantage for a joining element is that the mechanical properties such as strength and modulus of elasticity in martensite have significantly lower values than in austenite. Since the shape recovery occurs in the transition from detwinned martensite to austenite, the shape memory alloy must be present in the martensite in the joined state. As a result, the material can only develop a fraction of its potential.

The present invention is based on the object of solving the problems known from the prior art and of providing a joining element that is economical to manufacture and use and can withstand mechanical loads, which is stable in the technically relevant temperature range and enables very easy disassembly.

To solve the problem defined above, the present invention discloses a joining element according to claim 1. The joining element according to the invention is used to produce a releasable joining connection and consists at least partially of a Shape memory steel and can be deformed into a joining state by deformation to produce a joining connection with a joining partner, starting from a basic state, and can be at least partially deformed back from the joining state into a disassembly state to remove the joining connection by applying heat.

Shape memory alloys based on iron are referred to as shape memory steels. Two base alloy systems are currently known: Fe-Mn-Si and Fe-Ni-C. The solution according to the invention uses the very special properties of shape memory steel to create inexpensive, stable connections that can be easily detached after use. The advantages of this alloy for connecting elements, in particular for mechanically connecting components, lie in the mechanically induced martensite formation and the wide temperature range of most applications in which the connecting elements according to the invention are stable, since reconversion only begins at approx. 50 - 80 ° C 200 - 300 °C is completed. Furthermore, the mechanical properties are phase-independent.

In addition, shape memory steels have significantly lower material costs and process costs, since processes for the conventional production of high-alloy stainless steels can be used and the shape memory steels have good processability, similar to other high-alloy steels. Good mechanical properties such as high modulus of elasticity, high strength and very high elongation at break are further advantages of joining elements made of shape memory steel.

The properties of shape memory steels can be attributed to a deformation-induced one-way effect. The one-way effect of shape memory steels is based on a deformation induced by mechanical stress, during which Shockley partial dislocations are formed. These lattice defects are split dislocations that do not move atomic layers a full atomic distance, allowing the formation of reversible e-martensite. These dislocations can be reversed by applying heat (approx. 50 - 300 °C), which results in macroscopic shape recovery. In contrast to the classic shape memory alloys, the recovery is not 100% (80% or less depending on the forming). Thermal martensite only forms at very cold temperatures (below -20 °C) and is not relevant for most applications. The hysteresis is very large at over 150 K. Another important property for fasteners is that shape memory steels, in contrast to thermoelastic shape memory alloys, are not subject to any change in mechanical properties due to phase changes.

Advantageous developments of the invention are the subject of the dependent claims. It can be advantageous if the shape memory steel is an iron-based shape memory alloy, preferably an Fe-Mn-Si alloy or an Fe-Ni-C alloy. Iron-based shape memory alloys demonstrate a good non-thermoelastic shape memory effect in combination with good machinability, corrosion resistance and low material and production costs. Fe-Mn-Si alloys are cost-effective and have good machinability and good weldability.

It can prove to be useful if the joining element has at least one joining section, which preferably consists entirely of shape memory steel. The joining connection can therefore be designed according to the joining partners. In addition, a targeted change in shape of the joining element can be made possible when heated.

It can be helpful if the joining element is designed as a female joining element and has a receptacle in which a male joining partner can be inserted in the basic state and is non-positively and/or positively fixed in the joined state, in particular by reducing or tapering the receptacle, the receptacle being in the dismantling state is expanded relative to the joining state in order to release the joining partner arranged therein. Thus, by enclosing the male joining partner by the female joining element, a firm connection between the female joining element and the male joining partner can be guaranteed. In addition, the releasability of the joining element is improved, since only heating needs to take place and accessibility for mechanical release with high forces does not have to be guaranteed.

It can prove to be advantageous that the joining element is designed in a ring shape and has an opening as a receptacle into which a male joining partner can be inserted in the basic state and is fixed in the joining state and can be pulled out in the dismantling state. This makes it easier to assemble the joining partner into the joining element. Additional joining components can be easily added using a through hole and plugged onto one of the male joining partners.

It can be advantageous if the joining element is designed as a male joining element, preferably as a cylindrical or cuboid-shaped cross-section and can be inserted into a female joining partner that has a receptacle in the basic state and is fixed in a force-fitting and/or form-fitting manner in the joining state, in particular by widening the cross section, the cross section being reduced in the dismantling state compared to the joining state in order to release the joining partner arranged therein. Thus, by enclosing the female joining partner by the male joining element, a firm connection can be created between the male joining element and the female joining partner be guaranteed. In addition, the releasability of the joining element is improved, since only heating needs to take place and accessibility for mechanical release with high forces does not have to be guaranteed.

It can be useful if the joining element is designed as a locking ring, hollow rivet or crimp shoe. Accordingly, the joining element is versatile and can be applied to a variety of conventional connection methods.

It can be practical if the shape memory steel is in the ground state as austenite and in the joined state as martensite. Thus, the martensite of the shape memory steel of the joining element can be returned to the dismantling state by heating.

It can prove to be useful if the joining element can be converted from the basic state into the joining state by narrowing, widening, lengthening, upsetting, squeezing, flanging, crimping, spreading, and pressing. Accordingly, the joining method for transferring the joining element into the joining state can be selected in a variety of ways and the joining element can be used in a variety of conventional joining methods.

However, it can also be useful if the joining element changes from the joining state to the dismantling state at a temperature in the range of 50 ° C - 300 ° C, preferably in the range above 100 ° C. The joining element therefore continues to have high stability and strength even at high temperatures. The joining element according to the invention therefore enables a reliable connection in a wide range of temperature applications.

It can be practical if the joining element exerts bending and/or shearing forces on a joining partner in the joined state. This causes a further stiffening of the adhesion between the joining partner and the joining element. A reliable connection between the joining partner and the joining element can thus be guaranteed.

To solve the problem defined above, the present invention discloses a system for producing a releasable joining connection, comprising a joining element, in particular according to one of the preceding claims, and a joining partner, wherein the joining element consists at least partially of a shape memory steel and for producing a joining connection with the joining partner Starting from a basic state, it can be deformed into a joining state by the action of force and can be at least partially deformed back from the joining state into a disassembly state by applying heat to remove the joining connection. To solve the problem defined above, the present invention discloses a method for producing and releasing a joining connection, comprising the steps: Step A: Providing a joining element which consists at least partially of a shape memory steel, in particular a joining element mentioned above. Step B: Establishing a joining connection of the joining element with a joining partner starting from a basic state of the joining element by applying force and deforming the joining element into a joining state. Step C: Elimination of the joining connection by at least partially deforming the joining element from the joining state into a dismantling state by applying heat. The joining connection can be used between steps B and C. This can be chosen for any length of time. There can be any length of time between the individual steps. The method according to the invention can be used to carry out a joining process holistically from its assembly to its disassembly. Such a method achieves the firm connection of components during the joining state and enables the resources to be reused after use. The disassembly state allows disassembly without additional tools or instructions. Economical dismantling is also possible without knowing or having to identify the structure of the components or the joining element (dismantling with an undetermined effective point possible).

It can be practical if, in step A, a large number of individual joining connections are made individually with a large number of joining elements. The process can therefore be parallelized and therefore carried out efficiently.

It can prove to be advantageous that a large number of joining connections are canceled together in step C. This means that a large number of joint connections can be transferred to the dismantling state at the same time through global heat input. A heat input can be applied to the large number of joining elements without the point at which the connection will be released being known. Such a method can save individual disassembly steps and therefore be highly cost-effective.

Further preferred developments of the invention result from combinations of the features that are disclosed in the description, the claims and the figures.

Short description of the characters

Show it:

Fig. 1 is a side view of a first embodiment of a joining element. Fig. 2A is a sectional view in the direction of section AA from Fig. 1 of the first

Embodiment of a joining element in a basic state.

Fig. 2B is a sectional view in the direction of section AA from Fig. 1 of the first

Embodiment of the joining element in a joining state.

Fig. 2C is a sectional view in the direction of section AA from Fig. 1 of the first

Embodiment of the joining element in a dismantling state returned by heat input.

3A shows a sectional view of a second embodiment of a joining element in a basic state.

3B shows a sectional view of the second embodiment of the joining element in a joining state.

3C shows a sectional view of the second embodiment of the joining element in a disassembly state that has been returned by heat input.

Fig. 4A is a top view of a variety of systems in the disassembly process.

Fig. 4B is a side view of a variety of systems in the dismantling process in a dismantling basin.

Detailed description of the preferred embodiments

[First Embodiment]

Fig. 1 shows a side view of a first embodiment of a joining element 1. The joining element 1 has a flat base plate 1A. Two joining sections 1B extend vertically upwards from the base plate 1A. There is a gap between the joining sections 1B. The joining sections 1B can therefore be formed independently of one another. Fig. 1 shows two joining partners 2A, in the form of round wires 2A, which are arranged on the base plate 1A of the joining element 1 with their faces inclined towards one another. The round wires 2A, 2B extend along the base plate 1A and lie in the longitudinal direction of the base plate 1A in the area of the two joining sections 1B, so that the end faces of the round wires 2A, 2B meet in the area of the gap of the joining sections 1B. The round wires 2A, 2B are shown shortened in the longitudinal direction. The joining element 1 is in the basic state, i.e. the joining element 1 is not mechanically connected to the round wires 2A, 2B. The joining sections 1B preferably consist entirely of shape memory steel.

Shape memory steel is an iron-based shape memory alloy, preferably an Fe-Mn-Si alloy or an Fe-Ni-C alloy. In contrast to the classic ones Shape memory alloys have no thermoelasticity (under normal conditions) and have a very large hysteresis. With shape memory steels, due to the lack of thermoelasticity, the mechanical properties of both austenite and martensite are the same.

Fig. 2A shows a sectional view in the direction of section AA from Fig. 1 of the first embodiment of the joining element 1 in a basic state. Fig. 2A shows that the joining element 1 has a U-shaped cross section and the U-shaped cross section forms two joining sections 1B. The U-shaped cross section includes a receptacle for the round wire 2B and forms a female joining element 1, while the round wire 2B represents a male joining partner 2B.

2B shows a sectional view in the direction of section AA from FIG. 1 of the first embodiment of the joining element 1 in a joining state. By applying a force F from the outside to the joining sections 1B, the joining element 1 is transformed into a joining state. As a result of the deformation into the joined state, the austenite of the shape memory steel changes into reversible martensite. In the joined state, the joining sections 1B enclose the round wire 2B in order to clamp the round wire 2B in a force-fitting manner and, if necessary, to lock it in a form-fitting manner in the receptacle. In the joining state, the joining element 1 exerts bending and/or shearing forces on the joining partner 2, 2A, 2B, here the round wire 2B. By reducing or tapering the receptacle, the round wire 2B is fixed in the joining element 1. Analogously, the round wire 2A is fixed to the base plate 1A of the joining element 1 by the further joining sections 1B (not shown). The connection process shown in Fig. 2B is called crimping. Depending on the design, the joining element can alternatively be transferred from the basic state to the joining state by tapering, squeezing, flanging, crimping or folding.

Fig. 2C shows a sectional view in the direction of section AA from Fig. 1 of the first embodiment of the joining element 1 in a dismantling state returned by heat input. The heat input 7 into the joining sections 1B causes the martensite to reshape into the austenite due to the shape memory effect. The joining sections 1B reform at least partially (the deformation compared to the basic state is at best between 2 and 8%). The receptacle of the joining element 1 in the dismantling state is thus expanded compared to the joining state and the round wire 2B arranged therein is released. The joining connection is canceled. Analogously, the round wire 2A is released by the further joining sections 1B of the joining element 1, which are subjected to the heat input 7 (not shown). The joining element 1 changes from the joining state (martensite) to the dismantling state (austenite) at a temperature in the range of 50 ° C - 300 ° C. [Second Embodiment]

3A shows a sectional view of a second embodiment of a joining element in a basic state. Fig. 3A shows a joining partner 2 in the form of a locking ring bolt 2, which is guided through a bore of two components 3, 4 to be joined (here sheets 3, 4). The joining element 1 in the form of a locking ring 1 made of shape memory steel is placed on the locking ring bolt 2. The joining element 1 is therefore ring-shaped and designed as a receptacle with an internal opening 1C. The inner diameter of the opening 1C of the locking ring 1 is larger than an outer diameter of the locking ring bolt 2. The locking ring 1 can therefore easily be placed on the locking ring bolt 2, or the male joining partner 2 in the form of the locking ring bolt 2 can be inserted into the female joining element 1. The two sheets 3, 4 to be joined are arranged between a head of the locking ring bolt 2 and the locking ring 1.

3B shows a sectional view of the second embodiment of the joining element 1 in a joining state. The joining process is similar to that of a conventional locking ring bolt. The element to be deformed, here the locking ring 1 made of shape memory steel, is pushed onto the locking ring bolt 2. The composite is then axially prestressed using a setting tool. This grips the locking ring bolt 2 in order to fix it, and then forms the locking ring 1 onto the locking ring bolt 2 by applying a force with a force F. The deformation that occurs leads to the formation of reversible martensite in the locking ring 1. The locking ring bolt 2 can have a tensile part with a predetermined breaking point, which breaks in a defined manner when the maximum forming force is reached and the connection is set.

3C shows a sectional view of the second embodiment of the joining element 1 in a dismantling state returned by heat input 7. By using the shape memory steel and its shape memory effect, the deformation of the locking ring 1 can be partially reversed by heating it to 200 - 300 ° C, so that the connection between the locking ring 1 and the locking bolt 2 is released. With a suitable holder, the locking ring 1 and the locking bolt 2 can separate from each other by gravity without the need for further intervention or tools.

The joining element 1 and the associated joining partner 2, 2A, 2B each form a system 5 for producing a detachable joining connection. It is within the scope of the invention that a joining element 1 can also form a releasable joining connection with different joining partners, such as the joining element 1 according to the first exemplary embodiment, which can clamp joining partners with different cross-sectional shapes and dimensions between the joining sections. Also the joining element 1 after the second Embodiment example, a releasable joining connection can be formed with different joining partners, as long as the joining partners can be fixed in the joining state and released again in the dismantling state. The joining partner preferably consists of a harder material than the joining element, so that the joining connection can be easily released when the joining element is dismantled.

In general, the method for producing and releasing a joining connection with the present joining elements 1 from the exemplary embodiments can be summarized in the following steps: Step A: Providing a joining element 1, which consists at least partially of a shape memory steel. Step B: Establishing a joining connection of the joining element 1 with a joining partner 2, 2A, 2B starting from a basic state of the joining element 1 by applying force and deforming the joining element 1 into the joining state. Step C: Elimination of the joining connection by at least partially deforming the joining element 1 from the joining state into a dismantling state by applying heat.

4A shows a top view of a large number of systems 5 in the dismantling step. The multitude of systems 5 used in the joining state are collectively exposed to a heat input 7 from a heat source 6 in order to reform the joining elements 1 of the systems 5 and to transfer the joining elements 1 from a joining state to a dismantling state.

Fig. 4B shows a side view of a variety of systems 5 in the dismantling process in a dismantling container 8 or in a dismantling basin 8. The dismantling container 8 or the dismantling basin 8 are filled with a warm fluid and thus all joining elements 1 are reached by the fluid and transferred to the dismantling state. A disassembly method, as shown by way of example in FIGS. 4A and 4B, can thus parallelize the disassembly and therefore make it more economical.

Step C can therefore be carried out specifically by heating an individual joining element 1 or globally by heating an entire system 5 made up of joining element 1 and joining partner 2 or an entire collecting container of systems 5. Dismantling is therefore possible without knowing or having to identify the structure of the system 5 (dismantling with an undetermined effective point).

The present invention is not limited to the exemplary embodiments described. Further modifications and variations of the exemplary embodiments are conceivable within the scope of the claims. Analogous to the first or second embodiment, the idea according to the invention applies to all mechanical joining processes in which at least part of the joining element 1 consists of a shape memory steel, transferable. These are in particular rivet connections such as hollow rivets etc. and other crimp connections.

Reference symbol list

1 joining element

1A base plate

1 B joining section

1C opening

2, 2A, 2B joining partners

3 component, round wire, sheet metal

4 component, round wire, sheet metal

5 system

6 heat source

7 heat input

8 dismantling basins, dismantling containers

Claims

PATENT CLAIMS Joining element (1) for producing a detachable joining connection, wherein the joining element (1) consists at least partially of a shape memory steel and can be deformed into a joining state by deformation to produce a joining connection with a joining partner (2, 2A, 2B), starting from a basic state and can be at least partially deformed from the joined state into a disassembly state to remove the joint connection by applying heat. Joining element (1) according to the preceding claim, characterized in that the shape memory steel is an iron-based shape memory alloy, preferably an Fe-Mn-Si alloy or an Fe-Ni-C alloy. Joining element (1) according to one of the preceding claims, characterized in that the joining element (1) has at least one joining section (1 B) made entirely of shape memory steel, preferably consists entirely of shape memory steel. Joining element (1) according to one of the preceding claims, characterized in that the joining element (1) is designed as a female joining element (1) and has a receptacle in which a male joining partner (2, 2A, 2B) can be inserted in the basic state and in the joining state is fixed non-positively and / or positively, in particular by reducing or tapering the receptacle, the receptacle being expanded in the dismantling state compared to the joining state in order to release the joining partner (2, 2A, 2B) arranged therein. Joining element (1) according to the preceding claim, characterized in that the joining element (1) is annular and has an opening (1C) as a receptacle into which a male joining partner (2) can be inserted in the basic state and is fixed in the joining state and in Dismantled state can be pulled out. Joining element (1) according to one of the two preceding claims, characterized in that the joining element (1) is designed as a locking ring, hollow rivet or crimp shoe. Joining element (1) according to one of claims 1 to 3, characterized in that the joining element (1) is designed as a male joining element (1), preferably as a cylinder or cuboid with a cross section and in a female joining partner (2, 2A, 2B ), which has a receptacle, can be inserted in the basic state and is fixed in a non-positive and / or positive manner in the joined state, in particular by widening the cross section, the cross section being reduced in the dismantling state compared to the joining state in order to release the joining partner (2, 2A, 2B) arranged therein. Joining element (1) according to one of the preceding claims, characterized in that the shape memory steel is in the basic state as austenite and in the joining state is in the form of martensite. Joining element (1) according to one of the preceding claims, characterized in that the joining element (1) can be converted from the basic state into the joining state by narrowing, widening, lengthening, upsetting, squeezing, flanging, crimping, spreading, pressing or folding. Joining element (1) according to one of the preceding claims, characterized in that the joining element (1) changes from the joining state to the dismantling state at a temperature in the range of 50°C - 300°C, preferably above 100°C. Joining element (1) according to one of the preceding claims, characterized in that the joining element (1) in the joined state exerts bending and/or shearing forces and/or normal forces on a joining partner (2, 2A, 2B). System (5) for producing a releasable joining connection, comprising a joining element (1), in particular according to one of the preceding claims, and a joining partner (2, 2A, 2B), wherein the joining element (1) consists at least partially of a shape memory steel and for production a joining connection with the joining partner (2, 2A, 2B) can be deformed from a basic state into a joining state by the action of force and can be at least partially deformed back from the joining state into a disassembly state by applying heat to cancel the joining connection. Method for producing and releasing a joining connection, comprising the steps: a. Step A: Providing a joining element (1) which consists at least partially of a shape memory steel, in particular a joining element (1) according to one of the preceding claims. b. Step B: Establishing a joining connection of the joining element (1) with a joining partner (2, 2A, 2B) starting from a basic state of the Joining element (1) into a joined state by force and deformation of the joining element (1). c. Step C: Elimination of the joining connection by at least partially deforming the joining element (1) from the joining state into a dismantling state by applying heat. Method according to the preceding claim, characterized in that in step A a large number of individual joining connections with a large number of joining elements (1) are produced individually. Method according to claim 13 or 14, characterized in that in step C a plurality of joining connections are canceled together.