DE29805533U1 - Rotary piston drive - Google Patents

Description

PRINCE & PARTNERS

GbR

PATENT ATTORNEYS Manzingerweg 7

EUROPEAN PATENT ATTORNEYS D-81241 Munich

EUROPEANTRADEMARKATTORNEYS Tel. +49 89 89 69 80

TRW Occupant Restraint Systems GmbH
& Co. KG ^v

Industriestrasse 20
D-73551 Alfdorf ,

Our reference: T 8384 DE
St/Hc

Rotary piston drive

is V- ' "■■;.■ ■■ - ■' . ■■■.:■

The invention relates to a rotary piston drive, in particular for a belt tensioning mechanism, with a housing in which a working chamber with a substantially cylindrical outer wall is formed, a rotary piston which is mounted in the working chamber so as to be rotatable and concentric with the central axis of the working chamber and is provided with several sealing parts which protrude beyond the outer surface of the rotary piston and each form a working chamber between themselves and together with the outer wall, and with a compressed gas source which can provide a compressed gas for pressurizing the rotary piston so that it rotates in one direction of rotation.

Such a rotary piston drive, when used in a belt tightening mechanism, serves to eliminate the so-called belt slack from a seat belt system when necessary, by tightening the seat belt. This can be done by rotating a belt reel of a belt retractor in the winding direction or by moving an end fitting of the seat belt.

Such rotary piston drives are known in a wide variety of designs. The disadvantage is that the piston guide and the sealing movement of the components used to form the working chambers are relatively complicated.

The object of the invention is to create a simply constructed and robustly functioning rotary piston drive.

For this purpose, a rotary piston drive of the type mentioned at the outset is characterized in that a sealing element

. is provided, which is movably mounted in the housing and is in sealing connection with the outer surface or the sealing parts of the rotary piston. The movable sealing element ensures a very reliable seal, while at the same time a low-vibration rotary movement of the rotary piston is possible. .'

. Advantageous embodiments of the invention emerge from the subclaims. .

The invention is described below with reference to various embodiments shown in the accompanying drawings. In these:

Figure 1 is a perspective view of a belt tensioning mechanism using a rotary piston drive according to a first embodiment of the invention;

■ - Figure 2 is a perspective view of a belt tensioning mechanism with the cover removed, using a rotary piston drive, 3.0 according to a first embodiment of the invention:

- Figure 3 is another perspective view of the belt tensioning mechanism of Figure 2;

- Figures 4 to 8 each show a schematic plan view of the rotary piston drive according to the first embodiment in different rotational positions; ^;

- Figure 9 is a schematic plan view of a rotary piston drive according to a variant of the first embodiment;

&igr;. ' ■ ■ '■ . '

- Figure 10 is a perspective view of a belt tensioner -

5 Mechanism in which a rotary piston drive according to a' second

embodiment of the invention; -

'*: - Figure 11 shows another perspective view of the belt tensioner

Mechanism of Figure 10;

- Figures 12 to 17 each show a schematic plan view of

■ ■ the rotary piston drive according to the second embodiment in various

different rotational positions; ■

- Figures 18 to 21 each show a schematic plan view of a rotary piston drive according to a third embodiment of the invention. ., , , -

Figure 6 shows a schematic of a belt tensioning mechanism 2, which contains a frame 3 and a belt reel 4 rotatably mounted in it. A safety belt 5 is wound onto the belt reel 4.

At one axial end of the belt reel 5, a belt tensioning drive 6 engages

■ . ' which, if necessary, can act on the belt reel 4 in the belt winding direction. The belt tensioning drive contains in its

Inside there is a rotary piston drive that converts the drive energy provided by a compressed gas source into a rotary movement. The compressed gas source can be activated electrically via a signal line 7, for example. . ~

Figures 2 to 8 show a first embodiment of a rotary piston drive according to the invention. This essentially consists of a housing 10, a compressed gas source 12 and a rotary piston 14. A working chamber 16 is formed inside the housing 10, which has a substantially cylindrical outer wall 18. The compressed gas source 12 is connected to the rotary piston 14 via a

"; _: : Flow channel 20 is connected to an inlet chamber 22 which has a

- Has an outer surface 24 which forms a cylinder section. The inlet chamber 22 also has a pre-chamber 26.

An outlet opening 28 is formed in the housing through which the

Working chamber 16 is connected to the outside environment of the housing 10.

In the outer wall 18 of the working chamber 16, a ventilation channel 30 and an outlet channel 32 are also formed, which in the outlet opening ,28

flow. :

The rotary piston 14 has a cylindrical outer surface 34 and is mounted concentrically with the outer wall 18 of the working chamber 16 in the housing 10. On its outer surface 34, the rotary piston 14 is provided with three sealing parts^ which are made as one piece

, projections 36, 38, 40 formed with the rotary piston 14

The three projections are provided on the rotary piston 14 at equal distances from one another. Each of the projections has an outer contour such that a gear tooth is formed whose root circle coincides with the outer surface 34 of the rotary piston 14. Between the projections 36, 38, 40, a sealing layer 42, 44, 46 is provided on the outer surface 34 of the rotary piston 14, which ends at a distance in front of the corresponding projection 36, 38, 40 when viewed in the circumferential direction. . \

' : "'^;■■'■'',■■■■

Concentric with the outer surface 24 of the inlet chamber 22 is

a sealing element 48 is rotatably mounted in the housing, which is designed as a wheel and is provided with three vanes 50, 52, 54. The contour of the vanes is selected in such a way that a gear wheel with three teeth is formed, the geometry of the vanes 50, 52, 54 being adapted to the geometry of the projections 36, 38, 40 in such a way that the vanes and the projections can mesh with one another like two gear wheels. _;

, The projections 36, 38, 40 of the rotary piston 14 and the wings

50, 52, 54 of the wheel 48 lie tightly against the outer wall 18 of the working chamber 16 or the outer surface 24 of the inlet chamber 22. No special sealing materials are required for this, since the components can be manufactured in a simple manner with the required high precision. On the one hand, the outer wall 18 or the outer

■■■ ' surface 24 can be easily manufactured with particularly high precision, since it is a cylindrical surface, and on the other hand it is

.■..■■■■■■■■,. ■ ■ -5- ' ■

in the projections 36, 38, 40 and the wings 50, 52, 54 are merely rotating components, so that no oscillating radial forces

appear. ,

Î■■ ■ - · ■ ■■ ■ ■ ■ ■

5 ' In the initial position shown in Figure 4, the wheel 48 seals

. ,. " with its wings 52 and 54 against the outer surface 24 of the inlet chamber

22 and against the sealing layer 46 of the rotary piston 14. At the same time, the part of the working chamber 16 which lies between the outlet opening 28 and the seal formed by the vanes 52 and 54 is connected to the outside environment of the housing by means of the ventilation duct 30.

) ... - If in this state the pressure gas source 12 is a pressurized

■ standing gas is generated, it flows through the flow channel 20 into the

■< ' Pre-chamber 26 of the inlet chamber 22. The pressure generated there then acts

on the projection 36, and rotates the rotary piston 14 due to the pressure difference acting on the projection 36 in the direction of rotation of the rotary piston symbolized by the arrow P, whereby this rotation is transmitted to the belt reel 4.

In Figure 5, the rotary piston drive can be seen in the state in which the projection 40 meets the wheel 48. Due to the geometry of the projection 40 and the wings of the wheel 48, the rotary piston 14 rolls with its projection 40 and the wheel 48 with

&igr; its wings 52 and 54 act on each other like gears, whereby

a tight contact between the two parts is guaranteed at all times. Together with the contact of the wing 52 with the outer surface 24 of the inlet chamber 22, a working space is thus tightly delimited together with the projection 36.

After the projection 40 of the rotary piston 14 has rotated past the wheel 48 (see Figures 6 and 7), the rotary piston 14 is in the position shown in Figure 8, in which the wheel 48, together with the sealing layer 44 and the outer surface 24 of the inlet chamber 22, seals against the outlet opening 28. The

35", projections 36 and 40, is completely closed in this state; if the rotary piston 14 is rotated slightly further in its direction of rotation, this working chamber

. connected to the outlet opening 28 via the outlet channel 32. The

■ ' ■ ■ .' . ■ . -6- ' . ■ ■ "■■.·■

front end of the outlet channel 32 is spaced from the end of the pre-chamber 26 of the inlet chamber 22 at an angle that is slightly larger than the angle that separates the individual projections from one another, i.e., with three projections, slightly larger than 120°. In this way

f 5 ensures that there is always at least one lead for the

Sealing between the inlet chamber and the outlet channel 32 is available. /

Figure 9 shows a variant of the rotary piston drive according to the first embodiment. In contrast to the

In the first embodiment shown in Figures 2 to 8, the projections 60 are arranged adjacent to one another on the outer surface 34 of the rotary piston 14. When the rotary piston 14 rotates in its direction of rotation in the direction of arrow P, at least one projection 60 always meshes with the wheel 48 so that the latter rotates continuously. In this embodiment too, the wings 50, 52, 54 together with the projections 60 of the rotary piston 14 ensure

a permanent seal between the inlet chamber 22 and the outlet opening 28 as well as the ventilation duct 30. The ventilation duct 30 ensures in this variant in the same way as in the first

Embodiment that in the section of the working chamber located behind the outlet opening 28 relative to the direction ^of rotation no pressure

can build.

Figures 10 to 17 show a rotary piston drive according to the invention according to a second embodiment of the invention. Insofar as components are used in this embodiment that are known from the first embodiment, the same reference numerals are used. , .'■,·■

In this embodiment, the rotary piston 14 is also provided with three projections 36, 38, 40. However, these ^projections are provided with differently inclined flanks, with the flank at the front relative to the direction of rotation being flatter than the flank at the rear. The flank at the rear extends in an approximately radial direction. " ■ ■ ■ ■

,■■■■'.■ . - ^&eegr; - ' ' '

In this embodiment, a lever 70 is provided as a movable sealing element, which is pivotably mounted in the housing 10 by means of a bearing section 72. The lever 70 is provided with a sealing section 74 at its end remote from the bearing section 72, which rests with its free end on the rotary piston 14. The lever 70 together with the sealing section 74 extending approximately at right angles to it resembles a doctor blade that rests on the outer surface of the rotary piston. On the side of the lever 70 facing away from the rotary piston 14, a pressure chamber 76 is formed, which is in flow connection with the compressed gas source 12/. On its side facing the rotary piston 14, the lever 70 is exposed to the external pressure via a channel 78 and the outlet opening 28. Furthermore, the sealing section 74, which is designed with outer surfaces concentric with the bearing section 72, seals in the housing 10.

When the compressed gas source 12 generates a compressed gas, this flows via the inlet chamber 22 to the rotary piston 14. The projection 36 is then acted upon so that the rotary piston 14 rotates in the direction of the arrow P. The pressure also acting in the actuation chamber 76 acts on the lever 70 towards the rotary piston 14 so that the sealing section 74 securely seals against the outer surface 34" of the rotary piston 14. '

Figures 13 to 17 show various rotational positions of the rotary piston 14, by means of which it can be seen how the sealing section 74 enables the projection 40 to pass through. Since the front flank of the projection 40 is inclined, the sealing section 74 is pressed outwards as soon as the projection 40 rests against it. In all intermediate positions up to its most outwardly pressed position (see Figure 15), the lever 70, together with the sealing section 74 and the projection 40, seals securely against the outlet opening 28. When the projection 40 has passed the sealing section 74 (see Figure 16), the lever 70 together with the sealing section 74 is pressed again towards the outer surface 34 of the rotary piston 14 due to the pressure prevailing in the loading chamber 76, so that the seal is also ensured at this time.

Figures 18 to 21 show a rotary piston drive according to

a third embodiment of the invention. In this

- Embodiment are used as sealing parts instead of the projections

I, sealing levers 90, 92 are used, which can be pivoted by means of a bearing

■ ■'■' ■ - ' ^y , ' · ■ ' - ■

5 section 94 on the rotary piston. Each sealing lever

90, 92 is held by a spring 96 with its free end to the outer wall 18

of the working space 16. A ramp 98 is arranged in front of each sealing lever 90, 92 relative to the direction of rotation, which simultaneously forms a stop for the sealing levers 90, 92.

. ' ■ : . ':; .' ■■ ■" ■ · · ' ■■·■ ' ■·■.■-■

/ A lever 70 is provided as a movable sealing element, which

rests on the rotary piston 14 with its free end 74 opposite the bearing section 72, which forms a sealing section. &bull; ■ On the side of the lever 70 facing away from the rotary piston 14, a pressurization chamber 76 is formed, which is connected to the compressed gas source

12 is in flow connection. In addition, a spring 77 is provided which acts on the lever 70 towards the rotary piston 14. The lever 70 seals the side of the system facing the inlet chamber 22 against the outlet opening 28.
' 20 ~ " . . " ,.·■·■■

When the compressed gas source 12 generates a compressed gas, the rotary piston 14 is rotated in the direction of rotation P by the pressure acting against the sealing lever 90 in y. After a rotation of

a certain angle, the sealing lever 92 hits the lever 70 ': ■ , 25 (see Figure 19)'■ Through' the ramp 98, the lever 70 is thereby

pressed outwards, while at the same time the sealing lever 92 is pivoted towards the rotary piston by resting on the lever 70 against the action of the spring 96 (see Figure 20). It can be seen that in the state of Figure 20, in which the sealing lever 92 is not yet on the outer wall

18 of the working chamber 16, the sealing lever 90 ensures a seal ^1. The outlet channel 32 begins somewhat, more than 180° behind the end of the inlet chamber.

When the sealing lever 92 has moved under the lever 70 (see Figure 21), it is forced back into its position in tight contact with the outer wall 18 of the working chamber 16 due to the action of the spring 96 and the centrifugal force. At the same time, the

Lever 70 is again urged into contact with the outer surface 34 of the rotary piston 14 due to the effect of the pressure prevailing in the loading chamber 76 and the spring 77.

The flow losses that occur in the position shown in Figure 21, in which the lever 70 is not yet in its position in contact with the outer surface 34 of the rotary piston 14, only imperceptibly reduce the performance of the rotary piston drive.

10

Claims (23)

0 J 'Oil·) ) ·33 3 3 5 3 .DO-DS 3'1 13 PRINCE & PARTNERS GbR PATENT ATTORNEYS .' Manzingerweg 7 EUROPEAN PATENT ATTORNEYS D-81241 Munich EUROPEANTRADEMARKATTORNEYS Tel. +49 89 89 69 80 TRW Occupant Restraint Systems
GmbH & Co. KG
Industriestrasse 20
D-73551 Alfdorf Our reference: T 8384 DE . ' ... ■ Protection claims 1. Rotary piston drive, in particular for a belt tensioning mechanism, with a housing (10) in which a working chamber (16) with a substantially cylindrical outer wall (18) is formed, a rotary piston (14) which is mounted in the working chamber (16) so as to be rotatable and concentric with the central axis thereof and is provided with a plurality of sealing parts (36, 38, 40; 60; 90, 92) which protrude beyond the outer surface (34) of the rotary piston (14) and each form a working chamber between themselves and together with the outer wall (18), and with a compressed gas source (12) which can provide a compressed gas for acting on the rotary piston (14) so that it rotates in a direction of rotation (P), characterized in that a sealing element (48; 70) is provided ,25, which is movably mounted in the housing (10) and is connected to the Outer surface (34) or the sealing parts (36, 38, 40; 60; 90, 92) of the rotary piston (14) are in a sealing connection. 2. Rotary piston drive according to claim 1, characterized in ^that the sealing parts are formed as one piece with the rotary piston. projections (36, 38, 40; 60) are formed on the outer surface (34) thereof. '''.■'.■"'..-"■^.' ,-.:.,, ''■·'■;'·■ /v ^: ;>;;,. ',!^'ly ■ V, '■'':''/ 3. Rotary piston drive according to claim 2, characterized in that the projections (36, 38, 40; 60) have an outer contour such that each projection (36, 38> 4.0; .60) forms a gear tooth. ..-.,..-· -2- 4. Rotary piston drive according to claim 3, characterized in that the root circle of the formed gear tooth (36, 38, 40; 60) coincides with the outer surface (34) of the rotary piston (14). 5. Rotary piston drive according to claim 3 or 4, characterized in that the formed gear teeth (36, 38, 40) are arranged at a distance from one another on the outer surface (34) of the rotary piston (14) and that a sealing layer (42, 44, 46) is formed between the formed gear teeth (36, 38, 40) on the outer surface (34) of the rotary piston (14), which sealing layer ends at a distance from the corresponding tooth when viewed in the circumferential direction. 6. Rotary piston drive according to claim 3 or 4, characterized in that the formed gear teeth (60) follow one another directly. 7. Rotary piston drive according to one of claims 2 to 6, characterized in that the sealing element is a wheel (48) provided with several vanes (52, 54, 56), the axis of rotation of which is aligned parallel to the axis of rotation of the rotary piston (14) and the vanes (52, 54, 56) of which protrude into the path of movement of the projections (36, 38, 40; 60). 8. Rotary piston drive according to claim 7, characterized in that the wheel (48) is provided with three vanes (52, 54, 56), the Contour is selected such that a gear with three teeth (52, 54, 56) is formed, wherein the geometry of the wings (52, 54, 56) is adapted to the geometry of the projections (36, 38, 40; 60) such that the wings and the projections can mesh with one another.
30 9. Rotary piston drive according to one of claims 7 and 8, characterized in that the wheel is arranged in an inlet chamber (22), the rear side of which, viewed in the direction of rotation of the rotary piston (14), is sealed by the interaction of the vanes (52, 54, 56) with the rotary piston (14) and the outer surface (24) of the inlet chamber (22). 10. Rotary piston drive according to claim 9, characterized in -3- net that the outer surface (24) of the inlet chamber (24) forms a cylinder section and the wheel (48) is arranged concentrically with the outer surface (24) of the inlet chamber (22). 11. Rotary piston drive according to one of claims 9 and 10, characterized in that the inlet chamber (22) is provided with a pre-chamber (26) which, viewed in the direction of rotation of the rotary piston (14), is arranged in front of the axis of rotation of the wheel (48). 12. Rotary piston drive according to one of claims 9 to 11, characterized in that, viewed in the direction of rotation of the rotary piston (14), a ventilation channel (30) is formed behind the inlet chamber (22). 13. Rotary piston drive according to one of claims 1 and 2, characterized in that the flank of the projection (36, 38, 40), which lies at the front when viewed in the direction of rotation of the rotary piston (14), is set flatter with respect to the outer surface (34) of the rotary piston (14) than the flank lying at the rear. 14. Rotary piston drive according to claim 1, characterized in that the sealing parts are formed by sealing levers (90, 92) pivotably attached to the rotary piston (14), the free end of which rests against the outer wall (18) of the working space (16). 15. Rotary piston drive according to claim 14, characterized in that the sealing levers (90, 92) are spring-loaded. 16. Rotary piston drive according to one of claims 14 and 15, characterized in that in the direction of rotation of the rotary piston (14) a ramp (98) is arranged in front of each sealing lever (90, 92). 17. Rotary piston drive according to one of claims 13 to 16, characterized in that the sealing element is a lever (70) which is pivotally mounted in the housing (10) and is provided at its front end, viewed in the direction of rotation of the rotary piston (14), with a sealing section (74) which rests against the rotary piston (14). -A- 18. Rotary piston drive according to claim 17, characterized in that the lever (70) together with the sealing section (74) is designed in the manner of a doctor blade which rests against the rotary piston (14). 19. Rotary piston drive according to one of claims 17 and 18, characterized in that the sealing section (74) is inclined relative to the outer surface (34) of the rotary piston (14). 20. Rotary piston drive according to one of claims 14 to 19, characterized in that an inlet chamber (22) is provided which is arranged in front of the sealing section (74) when viewed in the direction of rotation of the rotary piston (14). 21. Rotary piston drive according to one of claims 17 to 20, characterized in that a loading chamber (76) is provided which is in flow connection with the compressed gas source (12), is arranged radially outside the working space (16) and whose side directed towards the rotary piston (14) is closed by the lever (70) so that, when the compressed gas acts in the loading chamber (76), the lever is loaded towards the rotary piston (14). 22. Rotary piston drive according to one of claims 17 to 21, characterized in that a compression spring (77) is provided which loads the lever (70) into contact with the rotary piston (14). 23. Rotary piston drive according to one of claims 17 to 22, characterized in that a ventilation channel (30) is formed behind the lever (70) when viewed in the direction of rotation of the rotary piston (14).