DE102022210729A1 - Arrangement for contacting a shape memory alloy element and locking device with such an arrangement - Google Patents

Abstract

An arrangement for contacting a shape memory alloy element is disclosed, wherein the shape memory alloy element can be transferred between a first shape of an extended position and a second shape of a retracted position along a force direction, wherein the arrangement comprises a first contact plate, a second contact plate, a first structure-giving element and a second structure-giving element, wherein the shape memory alloy element is arranged in mechanical contact between the first contact plate and the second contact plate in the force direction and these between the first structure-giving element and the second structure-giving element.

Description

The invention relates to an arrangement for contacting a shape memory alloy element and a locking device with such an arrangement.

Constructive solutions based on shape memory alloys can take on a variety of functions. There are several ways to thermally activate a shape memory alloy element.

Since shape memory alloy elements are typically electrically conductive, the option of applying current is often used for reasons of easy control and regulation. This means that a defined current flow is set above a certain voltage across the shape memory alloy element. The heat generated at this operating point is used to activate the shape memory alloy element.

• - Formgedächtnislegierungen bestehen aus Bestandteilen wie beispielsweise Nickel und Titan, bei denen gängige Löt- und Schweiß-Verfahren nicht anwendbar sind;
• - der für die Kontaktierung nötige Platzbedarf ist häufig nicht verfügbar und;
• - eine Kontaktierung beeinflusst die Kraftabgabe-Eigenschaften des Formgedächtnislegierungs-Elements negativ oder führt zu zusätzlichen Verlusten in Folge von Reibung.

A particular challenge arises in the arrangement and contacting of the active shape memory alloy element. This presents a variety of technical problems:

• - Shape memory alloys consist of components such as nickel and titanium, for which common soldering and welding processes cannot be used;
• - the space required for contacting is often not available and;
• - contact negatively influences the force delivery properties of the shape memory alloy element or leads to additional losses due to friction.

Particularly for mechanical locking systems that are to be produced in large quantities, high demands are placed on cost-effectiveness. This means that the production, assembly and operation of such a system must be economical.

To date, shape memory alloy elements have typically been contacted using complex crimping or clamping processes, which are time-consuming and costly.

It is therefore an object of the invention to provide an arrangement for contacting a shape memory alloy element which overcomes the disadvantages described above.

This object is achieved according to the invention by the arrangement for contacting a shape memory alloy element according to claim 1. Advantageous embodiments of the arrangement according to the invention are specified in subclaims 2 to 4. The object is also achieved according to the invention by the locking device according to claim 5. Advantageous embodiments of the locking device according to the invention are specified in subclaims 6 to 8.

The arrangement for contacting a shape memory alloy element according to claim 1, wherein the shape memory alloy element can be transferred between a first shape of an extended position and a second shape of a retracted position along a force direction, is characterized in that the arrangement comprises a first contact plate, a second contact plate, a first structure-giving element and a second structure-giving element, wherein the shape memory alloy element is arranged in mechanical contact between the first contact plate and the second contact plate in the force direction and these between the first structure-giving element and the second structure-giving element.

The advantage here is that the shape memory alloy element is not contacted by a crimp or clamp connection, but via the contact plates. The arrangement in the direction of force ensures secure contact throughout the entire operation. Other advantages include a simple structure with few parts, simple production of contact plates in terms of their geometry, the use of a standard connection technology for contacting the electrical connections on the contact plates, contacting without negatively affecting the output force of the shape memory alloy element, purely electrical control, the possibility of very high switching cycles without wear, simple assembly and a small size and thus easy integration into existing accessories.

In one embodiment of the arrangement according to the invention, the shape memory alloy element is arranged in a mechanically prestressed manner between the first contact plate and the second contact plate.

In a further embodiment of the arrangement according to the invention, the first contact plate and/or the second contact plate are made of conductive material.

In one embodiment of the arrangement according to the invention, connecting lines are attached to the two contact plates by standard Connection methods such as soldering, welding, clamping or screwing.

The locking device according to claim 5 comprises an arrangement according to the invention, a movable element and a housing, wherein one of the structural elements is fastened to the movable element and the other structural element is on the housing or part of the housing, so that the shape memory alloy element in the first shape of the extended position allows the movable element to at least partially emerge from the housing and in the second shape of the retracted position the movable element is retracted in the housing.

In one embodiment of the locking device according to the invention, it comprises electronics and connecting lines for controlling the shape memory alloy element.

In a further embodiment of the locking device according to the invention, it comprises a return spring which acts along the direction of force of the shape memory alloy element and presses the movable element in the direction of the retracted position.

In one embodiment of the locking device according to the invention, the return spring is designed as a compression spring.

The above-described properties, features and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of the embodiments, which are explained in more detail in connection with the figures.

• 1 Anordnung zur Kontaktierung eines Formgedächtnislegierungs-Elements;
• 2 Verriegelungsvorrichtung mit einer Anordnung zum Kontaktieren eines Formgedächtnislegierungs-Elements; und
• 3A und 3B Verriegelungsvorrichtung in der Eingefahren-Position und der Ausgefahren-Position.

Showing:

• 1 Arrangement for contacting a shape memory alloy element;
• 2 Locking device with an arrangement for contacting a shape memory alloy element; and
• 3A and 3B Locking device in the retracted position and the extended position.

In 1 an arrangement 100 for contacting a shape memory alloy element 500 is shown. The shape memory alloy element 500 can be transferred between a first shape of an extended position and a second shape of a retracted position along a force direction. According to the illustration in 1 this direction of force is horizontal.

The arrangement 100 according to the invention comprises a first contact plate 120, a second contact plate 130, a first structural element 110 and a second structural element 140. The shape memory alloy element 500 is arranged in the direction of force between the first contact plate 120 and the second contact plate 130 in mechanical contact, which in turn is arranged between the first structural element 110 and the second structural element 140.

Overall, it follows that the first structural element 110 holds the first contact plate 120 in the direction of force, then the shape memory alloy element 500 extends between the first contact plate 120 and the second contact plate 130 in mechanical contact and this second contact plate 130 is held by the second structural element 140.

The shape memory alloy element 500 is mechanically prestressed between the first contact plate 120 and the second contact plate 130. This maintains at least a minimum contact force between the shape memory alloy element 500 and the first contact plate 120 and the second contact plate 130. In other words, this means that in the retracted position of the shape memory alloy element 500, a minimum contact force is still applied between the shape memory alloy element 500 and the first contact plate 120 and the second contact plate 130.

The first contact plate 120 and/or the second contact plate 130 are made of conductive material. Connecting lines 125; 135 can be attached to these contact plates 120; 130. These connecting lines 125; 135 can be attached to the contact plates 120; 130 by standard connection methods such as soldering, welding, clamping or screwing. In the illustration of the 1 This zone 131 is marked with the attachment of the connecting cable 135 to the second contact plate 130.

In 2 a locking device 1000 according to the invention is shown, which in turn comprises an arrangement 100 according to the invention for contacting a shape memory alloy element 500. Furthermore, the locking device 1000 comprises a movable element 700 and a housing 710.

One of the structural elements 110 is attached to the movable element 700 and the other structural element 140 is attached to the housing 710 or is even part of the housing 710. The shape memory alloy element 500 can be In the first shape of the extended position, the movable element 700 at least partially emerges from the housing 710 and in the second shape of the retracted position, the movable element 700 is retracted in the housing 710. In the illustration of the 2 the shape memory alloy element 500 is in the second shape of the retracted position so that the movable element 700 is retracted in the housing 710 and does not protrude therefrom.

The locking device 1000 further comprises electronics 600 and connecting lines 125; 135 for controlling the shape memory alloy element 500. Furthermore, a return spring 510 is provided in the locking device 1000, which acts along the direction of force of the shape memory alloy element 500 and presses the movable element 700 towards the retracted position. This return spring 510 thus works against the force of the shape memory alloy element 500. When the shape memory alloy element 500 is energized accordingly, the force of the return spring 510 is overcome and the shape memory alloy element 500 is moved into the first shape of the extended position. The return spring 510 can be designed as a compression spring.

The 3A and 3B show the locking device 1000 according to the invention in the retracted position and the extended position. By energizing the shape memory alloy element 500, this can be transferred, for example, from the second shape of the retracted position to the first shape of the extended position, as shown in the 3B The movable element 700 protrudes from the housing 710 and can serve as a mechanical locking device.

The shape memory alloy element 500 is clamped between two structural elements 110; 140. A first contact plate 120 and a second contact plate 130 are arranged between the two structural elements 110; 140 and the shape memory alloy element 500. The arrangement in the direction of force and prestressing of the shape memory alloy element 500 ensures secure contact throughout the entire operation. The contact plates 120; 130 are made of a conductive material, so that electrical connections can be made very easily due to these material properties. Standard connection methods such as soldering, welding, clamping or screwing can be used here.

The locking device 1000 according to the invention can be a shape memory alloy element 500 in the form of a compression spring, which elongates when activated, and a return spring 510, whereby a mechanical locking including contacting and control is provided.

When not activated, the shape memory alloy element 500 is in the second shape of the retracted position and the movable element 700 is retracted in the housing 710. The return spring 510 presses the movable element 700 in the representation of the 3A and 3B to the right into the retracted position.

In 3B The activated state is shown. Here, the shape memory alloy element 500 was energized and thus transferred to the first shape of the extended position. The force of the shape memory alloy element 500 counteracts the restoring force of the return spring 510 and ultimately becomes greater than it. The movable element 700 then moves according to the representation of the 3B to the left and the movable element 700 comes out of the housing 710.

Claims (8)

Arrangement (100) for contacting a shape memory alloy element (500), wherein the shape memory alloy element (500) can be transferred between a first shape of an extended position and a second shape of a retracted position along a direction of force, characterized in that the arrangement (100) comprises a first contact plate (120), a second contact plate (130), a first structure-giving element (110) and a second structure-giving element (140), wherein the shape memory alloy element (500) is arranged in mechanical contact in the direction of force between the first contact plate (120) and the second contact plate (130) and these between the first structure-giving element (110) and the second structure-giving element (140). Arrangement (100) according to Claim 1 , wherein the shape memory alloy element (500) is arranged in a mechanically prestressed manner between the first contact plate (120) and the second contact plate (130). Arrangement (100) according to Claim 1 or 2 , wherein the first contact plate (120) and/or the second contact plate (130) are made of conductive material. Arrangement (100) according to one of the preceding claims, wherein connecting lines (125; 135) are attached to the two contact plates (120; 130) by standard connection methods such as soldering, welding, clamping or screwing. Locking device (1000) comprising an arrangement (100) according to one of the preceding claims, a movable element (700) and a housing (710), wherein one of the structural elements (110) is attached to the movable element (700) and the other structural element (140) is on the housing (710) or part of the housing (710), so that the shape memory alloy element (500) allows the movable element (700) to at least partially emerge from the housing (710) in the first shape of the extended position and the movable element (700) is retracted in the housing (710) in the second shape of the retracted position. Locking device (1000) according to Claim 5 , wherein the locking device (1000) comprises electronics (600) and connecting lines (125; 135) for controlling the shape memory alloy element (500). Locking device (1000) according to Claim 5 or 6 , wherein the locking device (1000) comprises a return spring (510) acting along the force direction of the shape memory alloy element (500) and pressing the movable element (700) towards the retracted position. Locking device (1000) according to Claim 7 , wherein the return spring (510) is designed as a compression spring.

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