DE102006011927A1 - Pyrotechnic actuator, has cylindrical housing with gas discharge port in peripheral surface, where discharge port is blocked by piston prior to activation and opened by motion of piston after activation - Google Patents

Abstract

The actuator has a cylindrical housing (11) whose both ends are open, and an electric ignition device disposed to block an opening portion at one end of the cylindrical housing. A piston and a piston rod are inserted into the cylindrical housing to be capable of an axial motion. The cylindrical housing has a gas discharge port in a peripheral surface, where the gas discharge port is blocked by the piston prior to activation and opened by the motion of the piston after activation.

Description

The The present invention relates to a pyrotechnic actuator. who in an automobile for an occupant restraint apparatus can be used.

In addition to Restraint devices of the airbag type used in vehicles as occupant restraints and as pedestrian protection apparatus For example, apparatuses for lifting also exist the hood of the vehicle in a collision to pedestrians too protect, and devices for retracting the steering wheel (retraction of the steering wheel forward into the vehicle).

These Apparatuses use an actuator of a pyrotechnic type, in which a piston using the force of an explosive is moved. The explosion energy is transferred to the piston as pressure, so that on the apparatus itself while applied to each phase after activation of the actuator pressure becomes.

In US 2003/0167959 A are an igniter 6 , a piston 8th and a piston rod 9 in a housing 2 . 3 arranged. At a peripheral wall portion of the piston 8th is an o-ring 15 intended. If the detonator 6 has been activated, the piston becomes 8th pushed away so that the piston rod 9 out of the case 2 . 3 protrudes.

The The present invention relates to a pyrotechnic actuator with a cylindrical housing, which is open at both ends, an electric ignition device, the one opening area closes at one end of the cylindrical housing, and a piston and a piston rod, which are inserted into the cylindrical housing so that they can perform an axial movement. The cylindrical housing has in a peripheral area a gas outlet port, with the gas outlet port in front blocked activation by the piston and after activation is opened by the movement of the piston.

embodiments The invention will be explained with reference to the drawing. Show it:

1 a longitudinal section of a pyrotechnic actuator;

2 a longitudinal section of another embodiment of a pyrotechnic actuator;

3 a longitudinal section of another embodiment of a pyrotechnic actuator, and

4 a view of an example of a protective apparatus for humans, in which the pyrotechnic actuator of 1 is provided.

If in the device known from US 2003/0167959 A after activation of the igniter 6 Gas is generated, which is the piston 8th so shifts that the piston rod 9 protrudes, then the gas can not escape and thus remains the inside of the housing 2 . 3 in a pressurized status. Then, when the pyrotechnic actuator from the vehicle body with the pressurized housing 2 . 3 can be removed, fragments and the like fly away as a result of pressure relief and cause injury to the workforce. Therefore, in consideration of operational safety, it is preferable, especially when disassembling a vehicle body, that this pressure-holding status of the actuator is not maintained.

One Aspect of the present invention is a pyrotechnic Specify actuator from which after an operation with gas pressure the pressure is drained to ensure operational safety during disassembly a vehicle body to increase.

Of the Cross-section in the width direction, which results from a cut through the actuator in a radial direction, should preferably a circular Mold in the cylindrical housing could have but also, if necessary, a triangular or quadrangular shape have, or a pentagonal, one hexagonal or another polygonal shape, or even an elliptical one Shape. The transverse cross-sectional shape of the piston seen in the transverse direction and the piston rod become dependent chosen from the cross-sectional shape of the cylindrical housing seen in the transverse direction.

The electric ignition device may be either a known electric igniter alone, or a Combination of an electric detonator and a small amount a gas generating agent.

The pyrotechnic actuator of the present invention has a gas outlet port in a peripheral surface of the cylindrical housing. The gas outlet port is blocked from activation by the electric ignition device, and is opened after activation. Thus, when the electric ignition device is activated, the piston performs a predetermined operation (an axial movement), after the gas is then discharged through the then open gas outlet port. A result of this gas blow-off is that the space between the electric ignition device and the piston remains in a pressure state with only reduced pressure (normal pressure or pressure near normal pressure), and that the piston returns to its pre-activation position, causing the piston Gas outlet connection blocked again. In this way, the pressurized status is eliminated and the reliability in dismantling the vehicle is improved.

Farther can by adjusting the opening cross-section of the gas outlet port, the time for discharging the gas (the Amount of gas that is released per unit of time) and can therefore also the retraction time for the piston and the piston rod can be adjusted. Under the hereby addressed Reciprocation is a process of understanding after which Activation of the electric ignition device the piston and the piston rod make a linear movement up to one execute maximum movement limit, and then return to their starting position. It should be noted preferably either multiple gas outlets at equal intervals in the peripheral area formed of the housing are, or that the gas outlet is designed so that the thrust which is generated when gas passes through the gas outlet port is drained.

The The present invention relates to a pyrotechnic actuator. wherein the piston has an outer diameter has, similar the inner diameter of the cylindrical housing, which outer diameter is larger as the diameter of the opening area of the cylindrical housing. The piston rod is integral with the piston and has an outer diameter, which is smaller than the diameter of the opening portion of the cylindrical Housing.

By Correlating the diameter of the piston with the diameter of the opening area of the cylindrical housing the piston can be prevented from activating from the cylindrical housing fly out.

The The present invention also relates to a pyrotechnic Actuator, wherein the cylindrical housing has an inwardly facing flange portion has at the side of the opening area, being the inward pointing flange area has a gas escape hole.

If the electric ignition device activated is, such that the piston and the piston rod a linear movement To run, becomes air which exists in the space surrounded by Piston, the piston rod and the cylindrical housing (air, which in the actuator during the production occurs) so that they are under increased pressure comes. Then this compressed air acts so that it is the linear one Extension movement of the piston and the piston rod obstructed. Of the on the piston after activation of the electric ignition device Actual pressure is considerable higher than the compression force of the air in the aforementioned space. However generated this compressed air, as long as this air is present in the room is a resistance to the linear motion of the piston and the piston rod. By placing the gas alignment hole in the inward facing Flange area, however, this space is kept under normal pressure, so that is why the linear movement of the piston and the piston rod uniform expires. It should be noted that the speed of movement of the piston and the piston rod can be adjusted by adjusting the opening cross-section the gas escape hole.

The The present invention also relates to a pyrotechnic Actuator in which the in the inwardly facing flange provided gas escape hole through a sealing tape or a sealing tape is blocked.

If the electric ignition device activated is, such that the piston and the piston rod a linear movement To run, then air in the space bounded by the piston, the Piston rod and the cylindrical housing, compresses and becomes her Pressure increased. This pressure acts so that it is the linear movement of the piston and the piston rod counteracts. If, however, in this room predetermined pressure is achieved (corresponding to the tensile strength of the sealing tape), then rips the sealing band, so that only then the gas escape hole in the inward pointing Flange area opened becomes. As a result, falls the internal pressure in the room and runs the linear movement of the piston and the piston rod uniformly. This structure is useful for Use in a case where the movement speed of the piston during one Operation changed becomes.

The Timing to rupture of the sealing band to open the gas escape hole is set by appropriate selection strength or strength (Thickness, material, adhesive and the like) of the sealing band and the diameter of the gas exhaust hole.

The present invention also relates to a pyrotechnic actuator, which further comprises a device which can be prevented may cause the piston to move before the pyrotechnic actuator is activated.

By Arranging such a device can prevent the piston from doing so will fly out of the cylindrical housing before the actuator is activated as a result of vibrations or the like, as during the normal use of the vehicle when driving on the pyrotechnic Actuator can act.

Of the Pyrotechnic actuator of the present invention may be in different Restraint devices for the people used in or on an automobile. Here, the term "human" describes both inmates of the automobile as well as pedestrians outside of the automobile.

In the pyrotechnic actuator of the present invention is to Activation time is a pressurized part before, however There is no longer any pressurized part after activation. So if the pyrotechnic actuator removed from a vehicle will, can No problematic situations occur involving fragments fly out and injure a mechanic as a result of the release the pressure, what would happen, if a pressurized part would still be present.

(1) The pyrotechnic actuator of 1 :

1 is a longitudinal sectional view of a pyrotechnic actuator 10 ,

An electric detonator 25 is in a metallic cylindrical housing 11 mounted, which are circular in cross section. The electric detonator 25 blocks an opening area 12 on one end side of the cylindrical housing 11 , At the other end side of the cylindrical housing 11 is an inward facing flange area 13 educated. One from the inward flange area 13 Surrounded part is called an opening area 14 Are defined.

The electric detonator 25 has an igniter collar 26 and an ignition area 27 , The electric detonator 25 is in the cylindrical housing 11 fitted so that the igniter collar 26 against a step area 15 is applied, which on an inner peripheral surface of the cylindrical housing 11 is provided. The electric detonator 25 is on the cylindrical housing 11 by crimping a peripheral edge (crimping area 16 ) of the opening area 12 set on one end side.

Multiple (for example between two and ten, and preferably between two and six) gas outlet ports 18 , z. B. holes are in a peripheral surface 17 of the cylindrical housing 11 provided with equal intervals in the circumferential direction. The diameter of the gas outlet connections 18 is determined considering the relationship with the reciprocation time of a piston 30 and the like, and may be e.g. B. between 0.5 and 3.0 mm, and is preferably between 1.0 and 2.0 mm.

The metallic piston 30 can be an axial movement in the cylindrical housing 11 To run. The outer diameter of the piston 30 is substantially identical to or only slightly smaller than the inner diameter of the cylindrical housing 11 , but is greater than the diameter of the opening area 14 , As a result, the piston can 30 perform a sliding movement, wherein the outer peripheral surface of the piston 30 is in contact with the inner peripheral surface of the cylindrical housing 11 , or he can move with a small clearance between the outer peripheral surface of the piston 30 and the inner peripheral surface of the cylindrical housing 11 is present. In any case, between the outer peripheral surface of the piston 30 and cylindrical housing 11 a lubricant may be provided to allow the piston 30 can move smoothly. In the pyrotechnic actuator 10 leads the piston 30 only a single reciprocation, and therefore the sliding movement is not a problem.

At its lower part has the piston 30 a cylindrical apron section 31 , The ignition range 27 the electric detonator 25 is in a columnar space 19 positioned from the apron section 31 is surrounded. An open end surface of the apron section 31 lies on the igniter collar 26 at. By assembling the apron section 31 and the electric detonator 25 becomes the piston 30 held in place. The outer peripheral surface of the skirt portion 31 lies the gas outlet connections 18 either very close to or even in contact with it, thereby giving the gas outlet connections 18 from the apron section 31 are blocked.

With the piston 30 is a metallic piston rod 32 integrally formed. The outer diameter of the piston rod 32 is smaller than the outer diameter of the piston 30 and is approximately equal to or slightly smaller than the diameter of the opening area 14 in the cylindrical housing 11 , As a result, the piston rod 32 perform a sliding movement, wherein the outer peripheral surface of the piston rod 32 with the opening area 14 is in contact, or there may be a slight clearance between the outer peripheral surface of the piston rod 32 and the opening area 14 , In any case, between the outer peripheral surface of the piston rod 32 and the opening area 14 a lubricant may be provided. In the pyrotechnic actuator 10 leads the piston rod 32 only a single reciprocation, so that the displacement movement is not a significant problem.

A top 33 the piston rod 32 is flat and in the same plane as the inward facing flange area 13 , An axial movement of the piston 30 and the piston rod 32 before activation is prevented by crimping a peripheral edge of the opening (flare 20 ) of the inwardly facing flange portion 13 (Opening area 14 ). It should be noted that the top 33 the piston rod 32 before activation to the outside from the opening area 14 can protrude. It should also be noted that a cylindrical space 22 between the piston rod 32 and the cylindrical housing 11 can be under normal pressure.

In 1 is the top 33 the piston rod 32 just. However, the top can 33 also inclined or curved, depending on the use of the human restraining apparatus, more specifically in accordance with the shape of another member constituting the top 33 contacted. In addition, on a part or on the entire plane, the inclined or curved top 33 Irregularities be formed.

Next is an operation of the pyrotechnic actuator 10 described. If the electric detonator 25 is activated, gas is generated (or heat, shock waves or the like), which causes the internal pressure to columnar space 19 increases. Upon exposure to this increase in internal pressure in the columnar space 19 leads the piston 30 an axial movement, wherein he the crimping 20 breaks through so that the piston rod 32 from the opening area 14 goes outside. At this time, the cylindrical space becomes 22 compressed, which leads to an increase in pressure. Due to sufficient pressure caused by the activation of the electric detonator 25 is generated, the piston rod can 32 from the upper surface of the cylindrical housing 11 extend to a sufficient extent. The piston rod 32 stops in motion when a shoulder area 35 of the piston 30 on an inner surface 21 the inwardly facing flange area 13 hits (status of stopped movement = maximum movement status).

During this process also leads the apron section 31 of the piston 30 an axial movement. This will increase the volume of the columnar space 19 enlarged and become the gas outlet connections 18 Approved. The high pressure gas in the columnar space passes through the gas outlet ports 18 blown off and takes in the result of the internal pressure in the columnar space 19 from. When the internal pressure in the columnar space 19 no longer sufficient, the piston 30 and the piston rod 32 to support, and also because of the internal pressure of the cylindrical space 22 , then return the piston 30 and the piston rod 32 back to their positions before activation. At this time, the internal pressure in the columnar space 19 reduced to normal pressure or almost to normal pressure (there is no more pressurized part), so that therefore the reliability during a later disassembly is ensured.

By adjusting the output power of the electric detonator 25 or the total opening area of the gas outlet connections 18 , or by adjusting both parameters, the reciprocation time for the piston 30 and the piston rod 32 (the time required between the status before activation to the stopped movement status and back to the pre-activation status). The entire opening area of the gas outlet connections 18 is set by selecting the diameter and / or the number of gas outlet ports 18 ,

When in 1 for example, the entire opening area of the gas outlet connections 18 is increased (and the output of the electric igniter 25 remains constant), then the amount of gas that is released when the gas outlet ports increase 18 by the movement of the piston 30 and the piston rod 32 Therefore, the time required for the stopped movement to return the piston is shortened 30 and the piston rod 32 (the reciprocation time of the piston). On the other hand, the reciprocation time of the piston is prolonged when the entire opening area of the gas outlet ports 18 is reduced.

(2) The pyrotechnic actuator of 2 :

2 is a longitudinal sectional view of a pyrotechnic actuator 100 , The in 2 shown pyrotechnic actuator 100 has a substantially identical structure as the pyrotechnic actuator 10 from 1 , Therefore only different parts of it are explained. Reference numerals such as in 1 used, lift identical components in 2 out.

In 2 is in the peripheral surface of the ignition region 27 the electric detonator 25 an annular groove 28 intended. In the annular groove 28 is an O-ring 29 fitted. The O-ring 29 is made of rubber or plastic and contacts the inner peripheral surface of the skirt portion 31 of the piston 30 , The through the contact between the O-ring 29 and the inner peripheral surface of the skirt portion 31 generated frictional force acts to cause axial movement of the piston prior to activation 30 and the piston rod 32 prevented. The beaded area 20 of the 1 is not provided in this case. It is possible, however, that both the O-ring 29 as well as the beaded area 20 are provided with each other.

(3) The pyrotechnic actuator of 3 :

3 is a longitudinal sectional view of a pyrotechnic actuator 200 , The in 3 shown pyrotechnic actuator 200 has a substantially identical structure as the pyrotechnic actuator 10 from 1 , Therefore only different parts of it are explained. Identical reference numerals, as in 1 , lift identical components in 3 out.

In the inwardly facing flange area 13 is at least a gas escape hole 38 , z. B. a hole provided. In front of the gas escape hole 38 is from the inner surface 21 here, as in 1 shown an annular sealing band 24 taped. As the sealing band 24 For example, a strip of aluminum or stainless steel carrying an adhesive layer may be used. The tear timing of the sealing band 24 can be adjusted by correlating the thickness, material, type of adhesive and the like, of the sealing tape 24 with the diameter of the gas escape hole 38 , It should be noted that the gas exhaust hole 38 even open, and no sealing tape 24 is glued over it.

Next is an operation of the pyrotechnic actuator 200 explained. If the electric detonator 25 is activated, gas (or heat, shock waves or the like) is generated, which causes the internal pressure in the columnar space 19 increases. After the piston 30 this internal pressure increase in the columnar space 19 picks up the piston 30 moved to perform an axial movement, including the piston rod 32 performs an axial movement to out of the opening area 14 to stand out.

As a result of the movement of the piston 30 becomes the cylindrical space 22 compressed, resulting in an increase in air pressure therein. If the sealing tape 24 this pressure increase can not resist any longer breaks the tape 24 so that the gas escape hole 38 is opened and the internal pressure in the cylindrical space 22 drops rapidly. It follows that the linear movement of the piston 30 and the piston rod 32 drain quickly until the shoulder area 35 of the piston 30 on the inner surface 21 the inwardly facing flange area 13 strikes.

During this process also leads the apron section 31 of the piston 30 an axial movement. This will increase the volume of the columnar space 19 enlarged and become the gas outlet connections 18 Approved. In this way, the high pressure gas becomes in the columnar space 19 through the gas outlet connections 18 discharged, so that, as a result, the internal pressure in the columnar space 19 decreases. When the internal pressure in the columnar space 19 is no longer sufficient, the piston 30 and the piston rod 32 support, then return the piston 30 and the piston rod 32 back to their positions they had before activation. At this time, the internal pressure in the columnar space 19 decreased to normal pressure or near normal pressure. As a result, the reliability in case of later disassembly is ensured.

(4) An example in which the pyrotechnic actuator of 1 is used in 4 shown.

4 Fig. 10 is a view showing an example of a pedestrian protection apparatus (hood attaching apparatus of a vehicle) in which the pyrotechnic actuator 10 from 1 is used. It should be noted that the piston rod 32 with a fitting 60 connected, and therefore slightly before the activation of the opening area 14 of the cylindrical housing 11 protrudes. 4 illustrates only one operation using the pyrotechnic actuator 10 is executed, and does not reflect actual dimensions.

On each side in the width direction of a vehicle 50 is a pyrotechnic actuator 10 provided (although in the drawing, only a single pyrotechnic actuator 10 is illustrated). The piston rod 32 is in each case with a hood, z. B. a hood 51 connected, by a rod-shaped support 61 extending from both sides by two substantially semicircular fittings 60 is trapped (in the drawing is just a fitting 60 shown). The fitting 60 is at a predetermined position on the hood 51 fixed. The support 61 will be between the two fittings 60 in the width direction of the vehicle 50 held so that he can turn without falling out. The fitting 60 may have a curved surface coincident with the peripheral surface shape of the piston rod 32 corresponds. Alternatively, a fitting 60 can be used with the shape of a flat plate, and can be the piston rod 32 that the fitting 60 contacted, have an at least partially planar shape.

By connecting the piston rod 32 and the hood 51 using the fitting 60 and support 61 in the manner described, the hood can 51 (or a trunk lid) can be made at an optional angle when the piston rod 32 raises or extends.

When the front of the vehicle 50 should collide with a pedestrian, then the electric detonator 25 activated by a command issued by an impact detection sensor. An electronic control unit (ECU) then issues the command and the result is the piston 30 and the piston rod 32 extended. This will make the hood 51 that with the piston rod 32 in contact, raised quickly. 4 shows a status in which the piston rod 32 raised to its upper limit.

If now the front surface of the vehicle 50 collided with the pedestrian, the pedestrian is often dug and against the hood 51 spun. In this case, though the hood 51 even soft, engine components such as a cylinder block and camshaft cover installed just below the bonnet would be extremely hard. If then the pedestrian against the hood 50 is hurled, he can with these hard components through the hood 51 colliding, which would increase the severity of an injury.

If, however, as in 4 shown the pyrotechnic actuator 10 is activated, then the hood flies 51 upwards, leaving between the hood 51 and the hard components, a gap is formed. As a result, the impact to which the pedestrian is exposed when he hits the bonnet 51 is significantly mitigated.

After a predetermined period of time (a period of time derived from past accident data and the like, and which is long enough to ensure that a pedestrian is indeed adequately protected), the piston rod returns 32 back to their position before activation, and the hood 51 also returns to the starting position. It is assumed that the pedestrian is then no longer in contact with the hood 51 and that therefore protection for the pedestrian has been sufficiently provided previously. Furthermore, the gas discharge acts through the gas outlet connections 18 so that it creates a cushioning effect when the pedestrian hits the hood 51 so that the shock to which the pedestrian is subjected is further mitigated.

Once the operation of the pyrotechnic actuator 10 is finished, the interior of the columnar space returns 19 back to normal pressure or almost normal pressure. Therefore, there is no more pressurized part when the pyrotechnic actuator 10 during dismantling or partial dismantling of the vehicle 50 removed after the accident. As a result, the reliability of the mechanics staff is ensured.

The The invention described in this way can, as is apparent is to be executed in different ways. Such variations do not leave the spirit and scope of the invention. Such modifications as those skilled in the art are obvious, should be from the scope of the following claims includes his.

Claims (5)

Pyrotechnic actuator with a cylindrical housing open at both ends ( 11 ), an electrical ignition device ( 25 ), which in the cylindrical housing ( 11 ) closes an opening area at one end of the cylindrical housing, and a piston ( 30 ) and a piston rod ( 32 ) which are axially movable in the cylindrical housing ( 11 ), characterized in that the cylindrical housing ( 11 ) in a peripheral surface thereof at least one gas outlet port ( 18 ), and that the gas outlet port ( 18 ) through the piston ( 30 ) closed before activation and after activation by the movement of the piston ( 30 ) is open. Pyrotechnic actuator according to claim 1, characterized in that the piston ( 30 ) has an outer diameter similar to an inner diameter of the cylindrical housing ( 11 ) and larger than a diameter of another opening area ( 14 ) of the cylindrical housing ( 11 ) and that the piston rod ( 32 ) integral with the piston ( 30 ) and has an outer diameter which is smaller than the diameter of the other opening area ( 14 ) of the cylindrical housing ( 11 ). Pyrotechnic actuator according to claim 1 or 2, characterized in that the cylindrical housing ( 11 ) on one side of the other opening area ( 14 ) an inwardly facing flange area ( 13 ), and that in the inwardly facing flange at least one gas escape hole ( 38 ) is provided. Pyrotechnic actuator according to claim 3, characterized in that the gas escape hole ( 38 ) in the inwardly facing flange area (FIG. 13 ) by a sealing tape ( 24 ) is blocked. Pyrotechnic actuator according to at least one of claims 1 to 4, further characterized by a device ( 28 ) to prevent the piston ( 30 ) before the pyrotechnic actuator ( 10 . 100 . 200 ) is activated.