EP2203648B1 - Pyrotechnical actuator - Google Patents

Description

The invention relates to a force element with a housing in which a piston with a pin is inserted longitudinally displaceable, and with a Anzündelement with contact pins, wherein the contact pins protrude at the connection side of the housing from the latter and the piston upon ignition of the ignition of the generated propellant gases in the direction is shifted to the actuating side until the pin protrudes on the actuating side of the housing, wherein the housing is integrally formed and cylindrical and the connection side with the end face of the housing is encircled by a cylindrical cover.

Such a force element is in the EP 1 469 205 A described.

For power elements, the housing has a support ring which carries the ignition element. This is relatively expensive to produce, but has the advantage of great mechanical stability.

The invention has the object of developing a force element according to the preamble of claim 1 so that the encapsulation facilitates, the necessary injection mold is easier and cheaper to make and thus the production costs are low. In addition, a method for producing this force element is to be specified.

According to the invention, this object is solved by the features of claims 1 or 3.

The housing according to the invention is formed in one piece and cylindrical and the connection side is encapsulated with the end face of the housing by a cylindrical cover enclosing. This eliminates a support ring, as is customary in the prior art. The number of parts is reduced.

On the outer circumference of the housing radial extensions are preferably arranged on the connection side, which are encapsulated or glued. As a result, the lid is fixed to the housing.

The ignition element is inserted except for the contact pins in the housing on the connection side.

The bottom of the ignition element, from which protrude the contact pins, is formed flush with the end face of the housing. The bottom of the ignition element forms a surface with the end face of the housing.

In the unactuated state of the force element of the piston abuts the ignition element. With unactuated state of the delivery state is referred to, in which the ignition element has not been triggered.

In one embodiment, the piston and the ignition element have the same diameter.

In another embodiment, the diameter of the piston is smaller than the diameter of the ignition element. In this case, preferably, the housing has a first bore into which the ignition element is inserted, and a second bore, in which the piston is inserted with the pin, wherein the first bore has a larger diameter than the second bore and both bores in the longitudinal direction of the housing adjacent to each other, whereby a paragraph is created, on which the ignition element is supported.

Circumferential grooves are advantageously arranged on the outer circumference of the piston, in which sealing rings are used.

An inventive method for producing such a force element is characterized in that prior to the encapsulation of the housing on the Connection side with the lid, the piston and the ignition element are inserted into the housing and is fixed during encapsulation of the piston and the ignition element is pressed onto the piston or the shoulder.

The invention will be explained in more detail with reference to two figures.

FIG. 1 shows a longitudinal section of an inventive force element with a one-piece cylindrical housing 1. One-piece throughout the text always refers only to the housing 1 without cover 10th

The housing 1 is open at its connection side 6, so that a piston 2 with a pin 3 can be inserted. The piston 2 has the same diameter as the inner diameter of the housing 1. On the actuating side 7, a bore is introduced on the end face of the housing 1, in which the pin 3 is guided. The piston 2 has on its outer circumference circumferential grooves 16, in each of which a sealing ring 17 is inserted, so that the piston 2 is guided sealed in the housing 1. Moves the piston 2 from its initial position (only this is in the FIG. 1 Shown in the end position, at the same time also displaces the pin 3, which has a smaller diameter than the inner diameter of the housing 1, so that the pin 3 protrudes from the housing 1 in the end position of the piston 2. This is used to mechanically trigger a process.

Seen from the operating side 7 from behind the piston 2, a ignition element 4 is inserted into the housing 1. The front side of the ignition element 4 abuts against the piston 2. From the bottom 11 of the ignition element 4 protrude two pins 5, which serve to direct the Anzündstroms in the ignition element 4. If the ignition element 4 is triggered by an ignition current, a propellant gas is formed which displaces the piston 2 and thus the pin 3 from the connection side 6 in the direction of the actuation side 7. As a result, the pin 3 comes out of the housing 1, which is used for control.

The bottom 11 of the ignition element 4 is designed to be flush with the end face 9 of the housing 1, so that only the contact pins 5 protrude out of the housing 1. For closing the housing 1, a cover 10 is provided, which surrounds the connection side 6. This cover 10 is overmolded.

In order for the cover 10 to be locked, radial extensions 8 are arranged on the connection side on the outer circumference of the housing 1. These extensions 8 are formed circumferentially, for example, on the outer circumference. The connection side 6 is thus encapsulated with the end face 9 of the housing 1 and with the extensions 8 of the cylindrical cover 10 encompassing. Only the contact pins 5 protrude from the lid 10.

This in FIG. 1 shown power element thus consists of only four parts, namely the housing 1, the piston 2 with pin 3, the ignition element 4 and the cover 10, which makes it inexpensive to manufacture.

FIG. 2 shows in a longitudinal section an alternative embodiment of a force element according to the invention. The housing 1 here has a first bore 12 into which the ignition element 4 is inserted and a second bore 13 into which the piston 2 is inserted with the pin 3, wherein the first bore 12 has a larger diameter than the second bore 13th having. Both holes 12, 13 adjoin one another in the longitudinal direction 14 of the housing 1, whereby a shoulder 15 is provided, on which the ignition element 4 is supported. With respect to the extensions 8 and the lid 10, this embodiment is with the in FIG. 1 shown identical.

Hereinafter, a method of manufacturing the aforementioned force member will be described. In a first method step, the piston 2 and the ignition element 4 are inserted into the housing 1 before the encapsulation with the cover 10.

During encapsulation (for producing a force element after the FIG. 1 ) the piston 2 is fixed and the ignition element 4 is pressed onto the piston 2 or the shoulder 15 and then the housing 1 with the cover 10 overmolded (for producing a force element according to the FIG. 2 ).

Claims (6)

1. An actuator with a housing (1) in which a piston (2) with a pin (3) belonging to the actuator is inserted longitudinally slidable, and with an ignition element (4) with contact pins (5) wherein the contact pins (5), project out of the housing (1) at the connecting end (6) of the housing (1), and wherein when the ignition element (4) is ignited the piston is displaced in direction of the actuating end (7) by the generated propellant until the pin (3) projects out of the housing (1) at the actuating end (7), wherein the housing (1) is formed as single part and cylinder-shaped, and wherein the connecting end (6) with the end face (9) of the housing (1) is extrusion coated in an encompassing manner by a cylinder-shaped cover (10), characterized in that the ignition element (4) is inserted up to the contact pins (5) into the housing (1) at the connecting end (6), and in that the bottom (11) of the ignition element (4), out of which the contact pins (5) project out, is formed aligned with the end face (9) of the housing (1), and wherein the piston (2) lies adjacent to the ignition element (4) when the actuator is in an unactivated state.
2. Actuator according to claim 1, characterized in that the piston (2) and the ignition element (4) have the same outer diameter.
3. An actuator with a housing (1) in which a piston (2) with a pin (3) belonging to the actuator is inserted longitudinally slidable, and with an ignition element (4) with contact pins (5) wherein the contact pins (5), project out of the housing (1) at the connecting end (6) of the housing (1), and wherein when the ignition element (4) is ignited the piston is displaced in direction of the actuating end (7) by the generated propellant until the pin (3) projects out of the housing (1) at the actuating end (7), wherein the housing (1) is formed as single part and cylinder-shaped, and wherein the connecting end (6) with the end face (9) of the housing (1) is extrusion coated in an encompassing manner by a cylinder-shaped cover (10), characterized in that the ignition element (4) is inserted up to the contact pins (5) into the housing (1) at the connecting end (6), and in that the bottom (11) of the ignition element (4), out of which the contact pins (5) project out, is formed aligned with the end face (9) of the housing (1), and wherein the diameter of the piston (2) is smaller than the diameter of the ignition element (4), and wherein the housing (1) comprises the first bore (12), in which the ignition element (4) is inserted, and comprises a second bore (13), in which the piston (2) with the pin (3) is inserted, wherein the first bore (12) has a greater diameter than the second bore (13), and wherein both bores (12, 13) align each other in longitudinal direction (14) of the housing (1) such that a recess (15) is built, against which the ignition element (4) is supported.
4. Actuator according to one of the claims 1 to 3, characterized in that radial protrusions (8) are arranged on the outer circumference of the housing (1) at the connecting end (6) which are extrusion-coated too.
5. Actuator according to one of the claims 1 to 4, characterized in that circulatory grooves (16) are arranged on the outer circumference of the piston (2) in which sealing rings (17) are inserted.
6. A method for manufacturing an actuator according to one of the claims 1 to 5, characterized in that before the extrusion coating of the housing (1) at the connecting end (6) with the cover (10), the piston (2) and the ignition element (4) are inserted into the housing (1), and during extrusion coating the piston (2) is fixed and the ignition element (4) is pushed to the piston (2) or to the recess (15).

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