DE3606021A1 - Rotary belt tightener for safety belts - Google Patents

Abstract

The invention relates to a rotary belt tightening unit for safety belts, having a rotatable motor casing and a deflection roller, which is arranged on the latter, for tightening the belt in the event of deceleration exceeding a preset level, by forming a belt loop. To improve the efficiency of belt tightening, measures are proposed which ensure that the rotating rotary cylinder rotates in a balanced manner without generating much friction. An eccentric design of the cylinder wall, which has free spaces, ribs and a second wall results in an extremely rigid construction which effectively counteracts deformation of the inner rotating surface under pressure. Furthermore, the eccentric bulge is arranged in such a way that its mass results in a balanced system of rotation. Both measures ensure that the running clearances, sealing gaps and rotational outlines are retained during the tightening phase and there is no loss of power. Furthermore, the increased outside diameter results in an increase in the belt tightening length of about 20-30 mm, without a larger installation space being necessary. <IMAGE>

Description

The invention relates to a rotary belt tensioner unit for a Seat belt that can be used in combination with a retractor or just for placed anywhere between a reel and a deflector.

Belt tensioners of this type are in EP 01 38 507, in the DE-OS 35 37 891 and in DE-OS 35 44 546 become known.

A rotary belt tensioner motor is arranged above a reel in a common or specially placed housing. If this belt tensioner is activated pyrotechnically by means of a gas generator, the motor housing rotates. A belt loop is formed over a deflection roller. Since the lower retractor locks, the webbing is drawn in from above, i.e. from the occupant over the deflector. Depending on the belt slack and resistance, the motor turns more or less far and thus tightens the belt more or less until the occupant moves forward about 20-25 ms after T _o and the load in the belt increases sharply.

The load is preferably carried out after the belt has been tightened in a clamping unit arranged above the belt tensioner.

As shown particularly clearly in FIG. 1 of DE-OS 35 44 546, the mass distribution in the rotating rotary cylinder of the belt tensioner motor is not optimal. It has been shown that the unbalance caused by the eccentric center of gravity causes an uneven loading of the sealing surfaces. The speed of the rotating belt tensioner motor is an average of 5,000 rpm with just a three-quarter turn total. The unbalance develops very strong radial forces.

The sealing surfaces are where the masses move radially overburdened. There is friction that is lost to the tightening performance. The areas of the sealing surfaces from which the masses move result in too large a sealing gap through which the pressure medium can escape can. This is also detrimental to the tensioning performance. So it shows that an imbalance in the rotating cylinder has negative effects has the efficiency of the belt tension.

The enormously high peak pressure when the propellant charge burns off (approx. 1,000 bar) acts as an elastic deformation on the cylinder wall of the Rotary cylinder. This elastic deformation of the cylinder wall when Turning in turn means a deviation from the constructive given geometric relationships. That is, the relative rotating parts (stator and rotating cylinder) the running games in Dependency on pressure and angle of rotation vary. The inner tread of the Rotary cylinder no longer corresponds to an ideal one during pretensioning Circle, but deforms more or less oval. From experiments has turned out shown that a maximum of elastic deformation after about 90 ° Angle of rotation occurs. The practical impact of such deformation, namely the change of the running contours and games, means in the end a partially increased resistance to rotation. If the running game becomes zero, one occurs Kind of self-locking on.

The amount of webbing to be pulled (to be tightened) is in a direct line Connection with the depth of the device. Should increase the stocking length the diameter (or) circumference of the rotary cylinder must be increased will. At the same time, this requires a correspondingly larger distance between the lower deflection axis, so that the circular arc described this deflection axis also gets bigger. This affects the construction volume. Because of the the available space is therefore only retractable The amount of webbing, which according to current knowledge is about 180 mm should not be arbitrarily definable. The optimization of size (depth) and Weight is therefore required in this system Minimum string length set certain limits.

The invention is based on the object

• a) make the design of the rotating mass so that the Center of gravity and the fulcrum coincide, so that a balanced rotary cylinder is executable.
• b) the rigidity of the cylinder wall of the rotary cylinder as large as possible to create an elastic deformation under pressure with a deviation from the given geometric contours to be avoided as far as possible.
• c) an embodiment of the rotary tensioner system in this way make that without influencing the external dimensions at the stand the technique allows a larger length of string to be retracted.

The solution to this problem arises including advantageous Refinements and developments from the content of this description preceding claims.

With the invention, the combined advantages are associated with that Designing a balanced rotating cylinder and running games Sealing surfaces during rotation are not negatively affected by any radial mass forces be influenced that also by the very rigidly trained A deformation of the given barrel contours, especially the inner tread, under pressure to a tolerable minimum is reduced and that finally through the eccentric design of the Shell surface to the inner tread with a large outer diameter Greater belt retraction length can be accomplished without the installation to enlarge the dimensions of the device.

In the drawing, an embodiment of the invention is shown. It demonstrate:

Fig. 1 A section through the belt tensioner motor

FIG. 2 shows a section from FIG. 1

Fig. 3 A section with the storage in a housing

From FIGS. 8 and 9 of EP 01 38 507, the operating principle of the Gurtstrammung is clear. DE-OS 35 44 546 shows a sensible form of load absorption after belt tightening. The belt tensioner motor 1 shown in the drawings of the present invention discloses the essential features of the invention. Fig. 1 shows a cross section without the reel arranged below and the clamping unit arranged above.

The clearest deviation from the prior art results from the eccentric arrangement of the lateral surface 15 relative to the inner running surface 23 . The theoretical maximum of the eccentricity e results from the fact that the point E on the outer surface 15 after a 180 ° rotation angle with a layer of webbing must still be able to turn freely on the housing wall 30 .

The two webs 7 and 7 'with the axes 9 and 10 and the guide roller 11 result in a fairly large eccentric mass. Due to the eccentric configuration of the cylinder wall 22 and the arrangement of the counter wing 6 diametrically opposite the webs 7 , there is the possibility of balancing the rotary body. The sprue 32 represents a balancing mass which, depending on the concentricity of the first drop pattern, can be made more or less large. This configuration of the rotating cylinder 2 enables a precisely balanced rotating mass.

Furthermore, the eccentric structure with the double wall and the ribbing means an enormous stiffening of the cylinder wall 22 . Where the double wall no longer exists, the stiffening of the cylinder wall is taken over by the two webs 7 and 7 ', so that there is a satisfactory all-round stiffness. These structural requirements ensure that the inner running surface 23 is sufficiently true to the contour, so that trouble-free rotation is ensured. The rigidity in combination with the balanced rotating mass of the rotary cylinder 2 ensure constant running play and sealing gaps, so that there is no loss of efficiency due to self-locking during belt tensioning.

The overall depth of the device is determined by the circular path 25 which the deflection roller 11 executes during the belt tensioner rotation. In this respect, the increase in the outer diameter of the rotary cylinder 2 does not represent an increase in the construction volume, provided the circular path 25 is not exceeded. The enlarged outer diameter results in a longer retractable webbing length. In practice, about 20-30 mm more webbing can be pulled in due to these conditions.

Fig. 2 shows a longitudinal section of the Gurtstrammermotors. 1 Apart from the propellant charge and the seals, which have not been shown for the sake of simplicity, the belt tensioner motor 1 consists of only 3 parts, the rotary cylinder, the stator 3 and the side window 4 . Due to the symmetrical design, the stator 3 can be mounted either on the level 28 or 27 either to the right or to the left. After insertion, the side window 4 is positively connected to the rotary cylinder 2 by flanging a web. The rotary cylinder 2 is preferably made of pressure casting. The free spaces 13 and ribs 12 are advantageously introduced from the side wall 31 . Due to the lateral arrangement of the hexagon 5 in the stator, simple assembly in the housing 30 can be accomplished, as shown in FIG. 3. The finished belt tensioner motor 1 is pushed into the U-shaped housing 30 , whereupon the stator 3 is connected to the housing 30 in a rotationally fixed manner by inserting two abutments 29 .

The mushroom-shaped configuration of the wing 8 from the stator 3 serves to enlarge the sealing surface according to the principle of the labyrinth seal.

• Terms 1 GS motor
  2 rotating cylinders
  3 stator
  4 side window
  5 hex
  6 counter wings
  7 bridge
  8 wings
  9 guide axis
  10 deflection axis
  11 pulley
  12 rib
  13 free space
  14 expansion room
  15 outer surface
  16 sealing surface 1
  17 sealing surface 2
  18 sealing surface 3
  19 sealing surface 4
  20 sealing surface 5
  21 sealing surface 6
  22 cylinder wall
  23 inner tread
  24 flares
  25 circular path
  26 webbing
  27 plane of symmetry
  28 plane of symmetry 2
  29 abutments
  30 housing
  31 side wall
  32 balancing mass

Claims (9)

1. Rotary belt tensioner for seat belts with a rotatable motor housing and a deflection roller arranged thereon for pulling in the webbing in an accident from a predetermined delay by forming a webbing loop, characterized in that the outer surface ( 15 ) of the rotary cylinder ( 2 ) is on a circular arc with the Radius ( R 2 ) extends around the point ( P ₂ ), the amount ( e ) against the webs ( 7 , 7 ') from the pivot point ( P ₁ ). 2. Belt tensioner according to claim 1, characterized in that on the rotary cylinder ( 2 ) of the counter wing ( 6 ) is arranged diametrically opposite the masses, which consist of the webs ( 7 , 7 '), the axes ( 9 , 10 ) and the Deflection pulley ( 11 ). 3. Belt tensioner according to claim 1, characterized in that the cylinder wall ( 22 ) of the rotary cylinder ( 2 ) extends to approximately 270 ° double-walled with free spaces ( 13 ) and ribs ( 12 ). 4. belt tensioner according to claim 3, characterized in that the free spaces ( 13 ) to the side wall ( 31 ) are open. 5. Belt tensioner according to claim 1, characterized in that the contour of the outer surface ( 15 ) is arranged eccentrically to the contour of the inner race ( 23 ). 6. belt tensioner according to the preceding claims, characterized in that the stator ( 3 ) with its wing ( 8 ) around the two planes ( 27, 28 ) is symmetrical. 7. belt tensioner according to the preceding claims, characterized in that the stator ( 3 ) is formed on both sides with a positive profile, preferably a hexagon for receiving abutments ( 29 ), the stator ( 3 ) rotatably with a housing ( 30 ) connect. 8. belt tensioner according to the preceding claims, characterized in that the wing ( 8 ) of the stator ( 3 ) has a mushroom-shaped contour with an enlarged sealing surface ( 17 ). 9. belt tensioner according to the preceding claims, characterized in that the connection of the rotary cylinder ( 2 ) and side window ( 4 ) via a circumferential flange ( 24 ).