DE102018201444A1 - Actuator unit for actuating a valve - Google Patents

Abstract

An actuator unit (AE) for actuating a valve (V) for a pneumatic adjustment device (PV) of a vehicle seat (FZS) is disclosed. The actuator unit (AE) comprises a printed circuit board (LP) having an actuation section (BA) for actuating the valve (V) and a shape memory alloy element (SMA) which is coupled to the actuation section (BA) and is deformable when electrical energy is supplied, the operating portion (BA) is moved to actuate the valve (V).

Description

The present invention relates to an actuator unit for actuating a valve for a pneumatic adjusting device of a vehicle seat. Furthermore, the present invention relates to a valve with such actuator unit.

In modern vehicle seats are with a pressure medium, in particular with a gaseous pressure medium, such as compressed air, fillable fluid chambers as adjusting elements in the region of the seat or seat back (together referred to as Sitzanlagefläche). Such fluid chambers can be supplied via a respective pressure medium line with the pressure medium. By filling or emptying a respective fluid chamber with pressure medium whose volume is increased or decreased, so that thereby the properties of the seat bearing surface, in particular its contour, can be changed. For filling the respective fluid chamber with pressure medium, the pressure medium is first generated by a pressure medium source, for example by a compressor or a compressor unit and controlled via a valve of a control device to a respective fluid chamber.

Frequently, shape memory alloy elements (also known as shape memory alloy elements = SMA elements) are used as the actuator unit for actuating such valves. The shape memory alloy elements are heated by supplying electrical energy, in particular electric current, whereby the shape memory alloying elements undergo a shape change. Upon completion of the supply of electrical energy, the shape memory alloy elements cool and return to their original shape.

This change in shape of the shape memory alloy elements can be used, for example, to operate a valve. For this purpose, the shape memory alloy element is typically electrically and mechanically connected to a printed circuit board and coupled to a movable actuator element which serves to open and close a fluid connection of the valve.

However, it has been shown that the use of a shape memory alloy element together with a separate actuator element, in particular during assembly of the valve, is complicated and cost-intensive, since the actuator element has to be arranged accurately and precisely in the valve and has to be complexly connected to the shape memory alloy element.

The object of the present invention is thus to provide an actuator unit for actuating a valve, in which it is possible to dispense with the use of a separate actuator element with minimal procedural and device complexity.

This object is solved by the subject matters of the independent claims. Advantageous embodiments are the subject of the dependent claims.

According to a first aspect of the invention, an actuator unit for actuating a valve for a pneumatic adjusting device of a vehicle seat is provided. The actuator unit has a printed circuit board with an actuating portion for actuating the valve and a shape memory alloy member which is coupled to the actuating portion and is deformable upon supply of electrical energy such that the actuating portion for actuating the valve is moved. By incorporating the operating portion for actuating the valve in the printed circuit board, it is no longer necessary to provide a separate actuator element for actuating the valve. By means of the operating section integrated in the printed circuit board, it is thus possible to provide an actuator unit with minimized procedural and technical complexity.

According to one embodiment of the actuator unit, the actuating section is defined by a recess present in the printed circuit board. The recess separates the actuating portion from the rest of the printed circuit board. As a result, the operating portion is integrated in the circuit board. For example, the recess may be a simple slot separating a portion of the circuit board from the remainder of the circuit board. The recess may also be in the form of a Us or Vs and at least partially enclose a region of the circuit board. The at least partially enclosed by the recess area then forms the operating portion of the circuit board. By the actuating portion is defined by a present in the circuit board recess, an operating portion can be created in the circuit board in a simple manner.

According to a further embodiment of the actuator unit, the shape memory alloy element is exclusively mechanically connected to the actuating section. For example, it is conceivable that the shape memory alloy element is a wire whose two ends are electrically and mechanically connected to the circuit board and are mechanically coupled in the form of a loop with the actuating portion. By means of this configuration, the actuating section can be provided without electrical conduction paths or contacts for supplying energy to the shape memory alloy element be formed, which further reduces the manufacturing and manufacturing costs.

However, according to a further embodiment of the actuator unit, it is also conceivable that the shape memory alloy element is electrically and mechanically connected to the actuating portion. In this embodiment, the actuation section has electrical conduction paths or contacts for supplying energy to the shape memory alloy element. For example, if the shape memory alloy element is a shape memory alloy wire, then one end of the wire may be connected to the attachment portion and the other end of the wire may be connected to the remainder of the circuit board. As a result, a particularly simple production of the actuator unit is possible.

In accordance with a further embodiment of the actuator unit, the printed circuit board has, in addition to the actuating section, a main section which is connected to the actuating section via a deformation section. The deformation section has a lower rigidity than the main section and / or the operating section. For example, as described above, when the operating portion is formed by a slit-shaped recess in the printed circuit board, the portion of the printed circuit board bordered by the slit-shaped recess may be used as the operating portion and the remaining portion of the printed circuit board may be used as the main portion, for example, for mounting in a valve body. Since the operating portion is connected to the main portion via a deforming portion having a lower rigidity than the main portion and / or the operating portion, it is possible to move the operating portion relative to the main portion to actuate the valve.

According to a preferred embodiment, the deformation region has a stiffness-weakened zone in order to achieve the desired (lower) stiffness. For example, the stiffness-weakened zone can be achieved by a material recess in the printed circuit board (for example in the form of small holes). However, it is also possible that the stiffness weakened zone is achieved by the use of a plasticizer. It is also conceivable that the stiffness-weakened zone has a different, in particular softer, material than the main section and / or the actuating section, for example rubber or a flexible polymer.

In a particularly preferred embodiment, the stiffness weakened zone is formed in the form of a groove, which is specially adapted to allow a smooth mobility of the actuating portion relative to the main portion. If the circuit board is a circuit board having an additional flexible layer (eg, a polyamide layer or a polyamide film), then the groove may be formed to extend to that flexible layer. The flexibility of the flexible layer can then be used, on the one hand, to achieve the desired (lower) stiffness in the deformation region and, on the other hand, to increase the mobility of the actuating section.

Furthermore, it is conceivable that the actuating portion has a smaller thickness than the main portion. Thereby, the flexibility of the operating portion is increased or the rigidity of the operating portion is reduced, so that the mobility of the operating portion is facilitated.

According to another preferred embodiment, the shape memory alloy element is a shape memory alloy wire having one end connected to the main portion and the other end connected to the operation portion. With this configuration, the shape memory alloy element can be electrically and mechanically connected in a simple manner to the printed circuit board or its main section and its actuating section.

In accordance with a further embodiment of the actuator unit, the actuator unit comprises an end position detection device which detects a movement of the actuation section that exceeds a predetermined threshold value. The use of an end-of-stroke detection device may be used to prevent over-threshold exposure of the shape memory alloy element to electrical energy (particularly, current). As a result, the life of the shape memory alloy element can be increased, which extends the field of use of the actuator unit.

According to a second aspect of the present invention, a valve for a pneumatic adjusting device of a vehicle seat is provided. The valve comprises a valve housing having a fluid port and an actuator unit according to the first aspect or embodiments thereof.

According to a preferred embodiment of the valve, the actuator unit is arranged in the interior of the valve housing such that upon supply of electrical energy to the shape memory alloy element, the actuating section is moved to open the fluid connection. Furthermore, in a preferred embodiment, the valve has a restoring element which is designed such that when the supply of electrical energy to the vehicle is stopped Shape memory alloy element, the actuating portion is moved to close the fluid port. By opening the fluid port upon supply of electrical energy to the shape memory alloy element and closing the fluid port upon completion of the supply of electrical energy to the shape memory alloy element, the actuator unit may be used in a valve which is closed when not energized ( so-called normally closed valve).

• 1 eine schematische Draufsicht auf eine Aktuatoreinheit gemäß einer Ausführungsform der Erfindung;
• 2 eine schematische Schnittansicht eines Ventils mit einer Aktuatoreinheit gemäß einer Ausführungsform der Erfindung, wobei das Ventil in einem geschlossenen Zustand gezeigt ist;
• 3 eine schematische Schnittansicht eines Ventils mit einer Aktuatoreinheit gemäß einer Ausführungsform der Erfindung, wobei das Ventil in einem offenen Zustand gezeigt ist; und
• 4 eine schematische Darstellung einer pneumatischen Verstelleinrichtung eines Fahrzeugsitzes, die ein derartiges Ventil aufweist.

In the following, exemplary embodiments of the invention will now be explained in more detail with reference to the accompanying drawings. Show it:

• 1 a schematic plan view of an actuator unit according to an embodiment of the invention;
• 2 a schematic sectional view of a valve with an actuator unit according to an embodiment of the invention, wherein the valve is shown in a closed state;
• 3 a schematic sectional view of a valve with an actuator unit according to an embodiment of the invention, wherein the valve is shown in an open state; and
• 4 a schematic representation of a pneumatic adjustment of a vehicle seat having such a valve.

Hereinafter, embodiments of the actuator unit will be described, which is used for actuating a valve for a pneumatic adjustment of a vehicle seat. Of course, the actuator unit can also be used to actuate valves used in other applications.

1 shows a schematic plan view of an actuator unit AE , which is used to actuate a valve V ( 2 to 4 ) for a pneumatic adjusting device PV (please refer 4 ) can be used.

The actuator unit AG has a circuit board LP on, the one operating section BA and a main section HA having. The main section HA is for example for attaching the circuit board LP formed in a valve housing. The operating section BA serves to actuate the valve V , as later related to the 2 to 4 will be described in more detail.

The operating section BA is in the present embodiment of 1 through a slot-like recess A in the circuit board LP Are defined. The recess A has a substantially U-shaped contour, so that the actuating portion BA in the form of a tab or a finger in the circuit board LP is trained. Of course, the recess A also have a different shape. For example, the recess A a V-shaped slot or any other slot, for example a simple straight slot, provided thereby one from the main section HA separated area arises, which is used to actuate the valve V suitable is. Incidentally, it is not necessary that the operating section BA inside the circuit board LP is arranged. For example, in other embodiments, the actuation portion BA also as a projection of the circuit board LP be educated.

The operating section BA is with the main section HA the circuit board LP over a deformation section VA connected. The deformation section VA has a lower rigidity than the main section HA and / or the operating section BA and allows flexibility of the operating section BA or a mobility of the actuating portion BA relative to the main section HA , In other words, the deformation section VA specially adapted to the actuating portion BA opposite the main section HA can be moved easily.

To the mobility of the operating section BA relative to the main section HA to allow the deforming section VA a stiffness weakened zone Z on that a certain flexibility or flexibility of the circuit board LP in the area of the stiffness-weakened zone Z allows. For example, the stiffness weakened zone may be a more flexible material than the printed circuit board material of the actuating portion BA and the main section HA respectively. It is also conceivable that the stiffness-weakened zone can be produced by the use of a plasticizer. Likewise, the stiffness-weakened zone can be produced by material recesses, for example in the form of small holes or holes.

In the concrete example of 1 the stiffness-weakened zone has a groove N on or is as a groove N trained (see also 2 and 3 ). By providing the groove N between the operating section BA and the main section HA the circuit board LP becomes the rigidity of the deformation section VA reduces, whereby the mobility or flexibility of the deformation section VA increases and thereby movement of the actuating portion BA relative to the main section HA is relieved.

As further in 1 is shown, the actuator unit AE on Shape memory alloy element ( SMA -Element) SMA on, in the concrete example of 1 is formed in the form of a wire. The shape memory alloy wire (short SMA -Wire) SMA has a first end E1 that with the main section HA electrically and mechanically connected, as well as a second end E2 that with the operating section BA electrically and mechanically connected, on. The electrical and mechanical connection between the ends E1 . E2 and the main section HA or the operating section BA takes place for example via a crimp connection. Of course, other, appropriate connections between the SMA -Wire SMA and the main section HA or operating section BA conceivable.

Although in the 1 the shape memory alloy element SMA as SMA Wire, one of which ends E1 with the main section HA is electrically connected, and the other end E2 with the operating section BA electrically and mechanically connected. However, in other embodiments it is also conceivable that both the first end E1 as well as the second end E2 electrically and mechanically with the main section HA is connected and the shape memory alloy element SMA For example, is designed as a sling, with the operating section BA is mechanically coupled only. In this embodiment can on line paths or electrical contacts in the region of the actuating portion BA be waived.

It is now up 2 refer, which is a schematic sectional view of a valve V with the actuator unit AE from 1 along the line AA from 1 shows, where 2 the valve V in a closed state. The valve V For example, for a pneumatic adjustment PV a vehicle seat are used, as related to 4 is explained in more detail.

As in 2 can be seen, the valve has V a valve housing VG on, a valve chamber or a pressure chamber DK limited. The valve housing VG also has a in the pressure chamber DK into opening 0 on that as a fluid connection FA for the valve V serves.

As in 2 can also be seen, is the actuator unit AE inside the valve body VG arranged. The actuator unit AE is so in the valve body VG arranged that the main section HA is substantially stationary connected to the valve housing VG. A the deformation section VA opposite end of the operating portion BA points to the opening 0 facing side a sealing element DE The trained, is the fluid connection FA close tightly.

On the the sealing element DE opposite side of the actuating portion BA (that is on the opening 0 opposite side of the actuating portion BA ) is a return element RE arranged in the form of a spring. The spring is with its one end to the valve body VG and with its other end to the attachment section BA coupled. The reset element RE thus generates a biasing force on the operating portion BA so that the operating section BA towards the fluid port FA is biased.

Will now be the shape memory alloy element SMA not subjected to electrical energy, then has the shape memory alloy element SMA its original shape or its original length. The biasing force of the return element RE then the operating section BA towards the fluid connection FA move so that the sealing element DE the fluid connection FA closes tightly. The movement of the operating section BA is doing by the deformation section VA that has a lower rigidity than the operating section BA and / or the main section HA has enabled. Because the deformation section VA a stiffness weakened zone Z with a groove N has, the actuating portion BA smoothly relative to the main section HA be moved or swiveled.

To the mobility of the operating section BA to increase, the actuating portion BA in the concrete example of 2 also a smaller thickness D1 as the main section HA on, whose thickness with D2 is designated. By the operating portion BA has a thickness D1 which is smaller than the thickness D2 of the main section, the flexibility of the operating section increases BA or reduces the rigidity of the actuating portion BA so that the operating section BA can be moved more easily.

It is now up 3 refer, which is a schematic sectional view of the valve V from 2 shows, where the valve V in 3 is shown in an open state.

The valve V is determined from the closed state ( 2 ) in the open state ( 3 ) transferred by the shape memory alloy element SMA is charged with electrical energy. In the supply of electrical energy to the shape memory alloy element SMA shortens the shape memory alloy element SMA , In that the shape memory alloy element SMA when SMA -Draht is formed, whose one end E1 with the main section HA and its other end E2 with the operating section BA is mechanically connected, the operating section moves BA against the biasing force of the return element RE and thereby opens the fluid connection FA , The mobility of the operating section BA in turn through the deformation section VA allows the stiffness weakened zone Z with the groove N having.

The in the 2 and 3 shown arrangement of the actuator unit AG in the interior of the valve housing VG allows a valve V to provide that in a non-electrically energized state of the shape memory alloy element SMA in a closed state is (normally closed). Of course, it is also conceivable that the actuator unit AE in the valve V is arranged such that the actuator unit AE in a normally open ( NO ) Valve can be used.

As well as in the 2 and 3 can be seen, the actuator unit AE an end-of-stroke detection device ELD which is designed to detect a movement of the actuating section BA that exceeds a predetermined threshold value. The end-of-stroke detection device ELD is in the specific example of 2 and 3 designed such that in the closed state of the valve V that is, in a state where the operation section BA in the non-deflected state relative to the main section HA is an electrical contact between the actuating portion BA and the main section HA consists. Will now be the shape memory alloy element SMA is charged with electrical energy and it comes because of the change in shape of the shape memory alloy element SMA to a deflection of the actuating portion BA relative to the main section HA , then becomes at a more than a predetermined threshold beyond movement of the actuating portion BA relative to the main section HA the contact between the operating section BA and the main section HA interrupted. The interruption of the contact may be used as a signal indicating that the operating section BA is located at a position which is a maximum allowable deflection relative to the main section HA equivalent. The signal generated by the interruption of the contact can thus be used as a protection signal, which is beyond a predetermined threshold exposure to the shape memory alloy element SMA prevented with electrical energy. In other words, the interruption of the contact may overheat the shape memory alloy element SMA prevents and thereby the life of the shape memory alloy element SMA be extended.

Of course, it is also possible that the Endlagendetektionsvorrichtung ELD is configured such that a contact between the actuating portion BA and the main section HA is not closed when the operating section BA in a non-deflected state relative to the main section HA is located, and that a contact between the operating section BA and the main section HA is closed only when the operating section BA is located at a position which is a maximum allowable deflection relative to the main section HA equivalent.

It is now up 4 refer, which is a schematic representation of a pneumatic adjustment PV a vehicle seat FZS showing the valve V from 2 and 3 having.

The pneumatic adjusting device PV has a fluid chamber FK located below a seat bearing surface SAF of the vehicle seat FZS located. By filling the fluid chamber FK with fluid or by emptying the fluid chamber FK can the size of the fluid chamber FK be changed, creating a contour of the seat bearing surface SAF in the area of the fluid chamber FK can be adjusted. The valve V is above the fluid connection FK fluidly with the fluid chamber FK connected, so that, for example, by opening the fluid port FA Fluid from the pressure chamber DK of the valve V into the fluid chamber FK can flow. The pneumatic adjusting device PV also has a fluid source FQ on, fluidly with the valve V via a previously described second fluid connection (schematically as FA2 shown) is fluidly connected. This can be done by the fluid source FQ For example, by means of a compressor (not shown) provided fluid via the fluid port FA2 in the valve V flow and controlled from there via the fluid connection FA into the fluid chamber FK stream.

Although in 4 not shown, the pneumatic adjustment PV have a second valve, which is identical to the valve V is and with the fluid chamber FK fluidly controlled connected and is connected to the environment fluidly non-controlled. By using such a second valve, the fluid chamber FK be emptied controlled.

Of course, it is also possible that a first actuator unit AE and a second actuator unit AE in a common valve housing VG can be arranged, which (by means of appropriate connections) both a filling and emptying of the fluid chamber FK enable.

Although the actuator unit AE has been described in connection with a valve that is used for a pneumatic adjustment of a vehicle seat, it is also possible that the actuator unit AE used in a valve that is used for other purposes.

Claims (13)

Actuator unit (AE) for actuating a valve (V) for a pneumatic adjusting device (PV) of a vehicle seat (FZS), comprising: - A printed circuit board (LP) with an actuating portion (BA) for actuating the valve (V) and - A shape memory alloy element (SMA), which is coupled to the actuating portion (BA) and is deformable upon supply of electrical energy such that the actuating portion (BA) for actuating the valve (V) is moved. Actuator unit (AE) to Claim 1 , wherein the actuating portion (BA) by a in the circuit board (LP) existing recess (A) is defined. Actuator unit (AE) to Claim 1 or 2 in which the shape memory alloy element (SMA) is exclusively mechanically connected to the actuating section (BA). Actuator unit (AE) to Claim 1 or 2 wherein the shape memory alloy element (SMA) is electrically and mechanically connected to the actuating portion (BA). An actuator unit (AE) according to one of the preceding claims, wherein the circuit board (LP) has a main portion (HA) connected to the operating portion (BA) via a deformation portion (VA) and the deformation portion (VA) has a lower rigidity than the main portion (HA) and / or the actuating portion (BA). Actuator unit (AE) to Claim 5 , wherein the lower rigidity of the deformation portion (VA) is achieved in that the deformation portion has a stiffness-weakened zone (Z). Actuator unit (AE) to Claim 5 or 6 , wherein the stiffness-weakened zone (Z) has a groove (N). Actuator unit (AE) according to one of Claims 5 to 7 wherein the operating portion (BA) has a smaller thickness (D1) than the main portion (HA). Actuator unit (AE) according to one of Claims 5 to 8th wherein the shape memory alloy member (SMA) is a shape memory alloy wire having one end (E1) connected to the main portion (HA) and the other end (E2) connected to the operation portion (BA). Actuator unit (AE) according to one of the preceding claims further comprising: - An end position detection device (ELD), which detects a movement beyond a predetermined threshold movement of the actuating portion (BA). Valve (V) for a pneumatic adjustment device (PV) of a vehicle seat (FZS), comprising: a valve housing (VG) having a fluid port (FA), and - An actuator (AE) according to one of the preceding claims, wherein the actuating portion (BA) for opening and closing of the fluid port (FA) is formed. Valve (V) after Claim 11 in that the actuator unit (AE) is arranged in the interior of the valve housing (VG) in such a way that, when electrical energy is supplied to the shape memory alloy element (SMA), the actuation section (BA) is moved to open the fluid connection (FA). Valve (V) after Claim 12 wherein the valve (V) comprises a return element (RE) adapted to move, upon termination of the supply of electrical energy to the shape memory alloy element (SMA), the fluid port (FA) closing operation section (FA).

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