DE102009057671A1 - Seat belt for vehicle, comprises partially tube-like belt strap which is filled with gas by using gas generator, where gas generator fills belt strap at vehicle-fixed filling station - Google Patents

Abstract

The seat belt comprises a partially tube-like belt strap (1,1a) which is filled with gas by using a gas generator (2). The gas generator fills the belt strap at a vehicle-fixed filling station (3). The belt strap is filled with a fraction of the gas of the gas generator through an injection point by a blowing channel. The belt strap is filled with another fraction of the gas of the gas generator through another injection point by another blowing channel.

Description

The invention relates to a safety belt for a vehicle having the features of the preamble of claim 1.

From the DE 2 008 048 A1 a seat belt for motor vehicles or aircraft is known, wherein parts of the belt or arranged on the belt bags, cushions or bags are inflatable by means of a pressure medium.

In the DE 198 21 996 A1 a webbing for an at least partially inflatable automatic safety belt is proposed. The webbing has a tubular fabric extending longitudinally with the webbing, which is folded. In the area of side edges of the webbing, the fabric is releasably connected to the webbing.

The generic DE 10 2006 003 794 A1 describes a safety system for occupants in a motor vehicle with a motor vehicle seat and a seat belt associated with the motor vehicle seat. The safety belt can be changed via a belt retractor in its extension length. In this case, the seat belt is connected to a gas generator, which in the presence of appropriate sensor data fills a hose body with gas and inflates, wherein a pull together with the safety belt gas supply connects the gas generator with the inflatable seat belt.

The object of the invention is to be able to fill an inflatable belt better with gas.

This object is achieved by the features of claim 1, wherein the features of the claims characterize advantageous embodiments and further developments.

The device according to the invention has a seatbelt for a vehicle, which comprises a webbing which can be filled with gas by means of a gas generator and which is at least partially tubular. The gas generator can fill the webbing in its tube-like belt webbing section at at least one point of insertion on the webbing through a web section of the tubular webbing section with gas at a vehicle-fixed filling location. The webbing is filled at the Einblasstelle by a first injection port with a first fraction of the gas of the gas generator and at another Einblasstelle by another injection port with a further fraction of the gas.

The first and the further injection channel are fed during the filling of the belt by a channel which directs the gas from the gas generator to the injection channels. The transition between the channel and the injection channels can be made by branching. The blow-in channels distribute the gas of the gas generator to various locations, which allows several advantageous embodiments for improved filling of the webbing. Examples of these embodiments will be described later.

In one embodiment, the fraction of the gas is predetermined by the flow resistance of the injection channel. Which fraction-also called the fraction-of the gas of the gas generator flows through the first injection channel and what proportion through the further injection channel results from the ratio of the flow resistance of the first injection channel to the flow resistance of the further injection channel. The flow resistance of the blow-in channels can be influenced, for example, via an effective flow cross-section of the blow-in channels. Among other things, the effective flow cross-section takes into account the smallest cross-section of the respective injection channel. The greater the flow resistance or the smaller the effective flow cross-section of the further injection channel compared to the effective flow cross-section of the first injection channel, the less gas will flow through the further injection channel in the filling of the webbing compared to the amount of gas, which at the filling flows through the first injection channel.

In the following, the division of the channel into the blow-in channels will only be considered if special versions are described. For more general considerations, this breakdown is not discussed.

The seat belt for the vehicle is used to tie down an occupant, so that in case of an accident accidental occupant load can be reduced. A safety belt usually used in vehicles comprises a fabric-like webbing, by means of which the occupant can be held back in the event of an accident. In a further development of the safety belt, an at least partially tubular webbing is filled with gas by a gas generator. Such inflated webbing allows a larger contact area between the webbing and the occupant, whereby a contact pressure of the webbing is reduced to the occupant. The contact pressure results from a force introduced in the event of an accident over the belt on the occupant restraint force, which is divided by the contact area between the belt and the occupant. An increase in the contact surface leads to a reduced contact pressure with the same retention force. Conventional devices for filling the belt with gas are expensive.

To fill the belt, the gas generator is activated, for example by an accident detection. Activation activates the gas generator. An exemplary embodiment of the gas generator is a pyrotechnic gas generator. In a pyrotechnic inflator, a pyrotechnic propellant is ignited by an electrical pulse that activates a filament or spark. The combustion of the propellant produces the gas. Another embodiment of the gas generator is a compressed gas storage. In a compressed gas storage is compressed gas, which thereby may also be liquefied. An activation of the compressed gas storage, whereby the gas flows out, can be done for example by an electrical control of an electrically open passage opening at the compressed gas storage. Another embodiment of the gas generator is a hybrid gas generator, which comprises both a pyrotechnic component and a compressed gas storage. Activation of the hybrid gas generator is accomplished in one embodiment by activating the pyrotechnic component. By activating the pyrotechnic component, the internal pressure of the hybrid gas generator increases, thereby breaking a first disc which seals an outlet port. Through the thus opened outlet both the gas of the pyrotechnic component and the gas of the compressed gas storage flows.

The webbing consists at least partially of a tubular webbing, the tubular webbing section. Unless the entire webbing consists of the tube-like webbing, the non-tubular webbing can consist of a usual for seat belts fabric-like webbing. The tubular webbing comprises in one embodiment a fabric tube, which may also be coated for sealing. The seal avoids or reduces gas flow through the fabric. The non-gas-filled tubular webbing can be folded up for a space-saving use position. To fix the position of use, the folded tube-like webbing can for example be sewn or glued, wherein the fixation is achieved by filling the webbing with gas. Filling the strap with gas can also be called inflating.

The gas generator may fill the webbing at the vehicle-fixed filling location. The position of the filling location is fixed relative to a shell of the vehicle. When the gas generator is activated, the webbing is filled at the injection point, which is located at the vehicle-fixed filling. The webbing is filled through the fabric section of the point of insertion. A separate opening of the webbing at the point of insertion is therefore not necessary for filling. The gas flows through the fabric of the webbing during filling.

When the webbing is slidably guided along its main extension direction at the vehicle-fixed filling location, the webbing is filled through the fabric section of the injection point, which is located at the time of filling at the vehicle-fixed filling location. As a result, a very simple filling of a tubular webbing with variable extension length is possible. Very common are three-point automatic straps, which draw a belt length that is not required with a belt retractor and roll up. A required belt length is unwound by pulling on the webbing from Gurtbandaufroller and output. In this way, the extension length of the webbing, which is required for buckling the occupant, vary. In a particularly advantageous embodiment of the tubular webbing portion is performed together with a three-point automatic belt. The tubular webbing section can be rolled up at least partially by the webbing retractor. The gas generator can at least partially fill the hose-like belt web section with gas, wherein the point of insertion varies as a function of the extension length of the webbing.

In one embodiment, an enclosure surrounds the webbing at the filling location. The enclosure causes always a portion of the webbing is located at the filling. When the belt is filled with gas by the gas generator, the enclosure supports the webbing and prevents the webbing from being reduced or prevented by the webbing pushing away or slipping. The enclosure may for example comprise a metal or plastic block in which a slot is inserted, through which the webbing passes. In addition to the slot, at least one protrusion may be incorporated in the enclosure. The bulge allows a widening of the tube-like webbing section during filling of the webbing with gas. An example of such a bulge is a funnel-shaped recess which widens from the point of insertion towards the occupant.

In an advantageous embodiment, the enclosure has at least one channel through which gas flows during filling of the webbing. In an extended version, the gas generator is attached to the enclosure. As a result, a stable structure or small dimensions of the assembly, which is formed from the enclosure with the gas generator, allows.

In a special embodiment, the enclosure has a component for guiding, filling or Shapes of webbing. The component is arranged rigidly, movably or rotating within the enclosure. If the component is rigidly disposed within the enclosure, the enclosure and component can be made in one piece.

In one embodiment, an angle between an inflow direction of the gas in the webbing and a surface of the webbing is set at the filling. The inflow direction is determined by the orientation of a blower to the surface of the webbing. The angle may be defined longitudinally or transversely to a main extension direction. Of course, two angles can be defined longitudinally and transversely to the main extension direction of the webbing. As a reference for the angle, the surface of the webbing is preferably fixed in the non-inflated state. Due to the angle, the inflation of the webbing can be significantly influenced.

When the inflow direction of the gas is set perpendicular to the surface of the webbing, the inflow direction is completely directed toward the inside of the tubular webbing portion. If the inflow direction is defined obliquely to the surface of the webbing, the inflow direction has a component of the inflow direction acting perpendicular to the surface of the webbing and a component of the inflow direction acting along the surface of the webbing. The component acting perpendicular to the surface of the webbing causes the gas to flow into the tubular webbing section. The component acting along the surface of the webbing can, for example, influence a longitudinal displacement of the webbing along its main extension direction, since the component acting along the surface of the webbing draws the inflow direction on the webbing in the direction of its flow direction.

When determining the angle between the inflow direction of the gas and the surface of the webbing, the further flow course of the gas after it has emerged from a blow-in channel can also be taken into account. For example, vortex formation can be avoided, reduced or supported by the choice of the angle. A vortex formation inside the tube-like webbing section can improve the filling of the webbing section, since layers of the webbing section can be spaced apart by a swirl. A vortex formation outside of the webbing section may worsen the filling of the webbing section, since the vortex formation reduces the velocity of the flow and thus the inflow into the webbing section.

In one embodiment, injection points are provided on opposite sides of the webbing. In an exemplary embodiment with two injection points, the inflow direction of the first injection channel is at least partially opposite to the further inflow direction of the further injection channel. An at least partially opposite inflow direction means that at least one component of the inflow direction and one component of the further inflow direction are opposite to one another. An opposite inflow direction of at least two gas streams can be used to ensure that the at least two gas streams meet in the interior of the tube-like belt webbing section and thus brake each other. As a result, further flow of the gas out of the tubular webbing section can be avoided or at least reduced. This allows a better filling of the webbing section or it allows a reduced sealing of the webbing section against escaping gas.

In one embodiment, at least one angle between an inflow direction of the gas into the webbing and a surface of the webbing at the filling location is determined such that during the filling of the webbing with gas, the webbing is at least partially sucked in at the filling location by the Bernoulli effect. According to the Bernoulli effect, which results from the law of Bernoulli, an increase in velocity of a flowing gas is accompanied by a pressure drop. By this pressure drop on one side of the webbing and a higher pressure on an opposite side of the webbing, the webbing can be sucked in the direction of the side on which the flow with the increase in speed is accompanied by the pressure drop. The suction of the webbing by the Bernoulli effect is stronger, the faster the gas flows parallel to the webbing. The gas flows at the same flow rate from a blower more quickly parallel to the webbing past, the smaller the angle between the inflow direction of the gas and the surface of the webbing. The smaller the angle, the less gas will flow into the webbing. If a blow-in channel allows the gas to flow out in the direction of the webbing at a low, that is to say shallow, angle, it is possible that no gas can flow into the tubular webbing section of the webbing from this blow-in passage.

The at least partial suction of the webbing by the Bernoulli effect can improve the filling of the tubular webbing section with gas. This is done in one embodiment in that a layer of the tubular webbing section is sucked in at one point by the Bernoulli effect and thus fixed, while an opposite position of the webbing portion is not fixed, is flowed through by a further injection channel with gas and can be removed by the inflation of the fixed position of the webbing section. An example of a coating of the webbing section conditional bonding of webbing layers, which can hinder or prevent the filling of the webbing section with gas can be counteracted by the partial suction of the webbing, whereby the inflation of the tubular webbing section is improved.

In one embodiment, the webbing is supported at the filling of a acting as a free-form support surface against a force acting on the filling of the webbing gas pressure. In a preferred embodiment, the webbing is guided at the filling of an enclosure. This enclosure may include the support surface. The support surface counteracts the gas pressure acting upon the filling of the webbing and prevents the webbing from dodging the gas flow during filling, whereby the filling of the webbing with gas would be reduced or prevented. The freeform is a flat surface in a simple design.

In another embodiment, the support surface is designed as a curved surface. In this case, a bending of the surface lead to a bending of the tubular webbing portion, whereby opposite layers of the webbing portion are shifted from each other, which favors a release of the layers from each other. The favored release of the layers, the filling of the webbing section is improved with gas.

With the curved support surface of the flow profile of the gas can be favorably influenced after its exit from a blow-in. As with an aerodynamic design of an outer shell of a vehicle or an aircraft can be favored by the shape of the free surface vortex formation of the gas flow, reduced or avoided.

In one embodiment, the webbing is filled with a partial amount of the gas of the gas generator in a pre-filling mode and then filled in a residual filling mode with a further subset of the gas. In Vorbefüllungsmodus the tubular webbing portion is filled with the subset of the gas only partially. In this way, for example, a pre-deployment of the tubular belt webbing section can be achieved. The pre-deployment of the webbing section may be necessary, for example, to separate successive folded layers of the webbing section from each other before the tubular webbing section is filled in the remaining filling mode with the further subset of the gas.

In the residual fill mode, the gas may flow better between the prefilter mode spaced layers of the tubular webbing than would be the case without the pre-fill mode with non-spaced webbing layers. The pre-filling mode may be particularly advantageous for a tubular webbing portion having a coated webbing as the webbing coating can releasably bond the folded webbing layers together. This releasable bond can be solved by the pre-filling mode. A two-stage gas generator, which comprises two gas generator units which can be activated separately from one another, can partially fill the webbing with its first gas generator unit in the pre-filling mode with the gas quantity of the first gas generator unit. After expiration of a time interval, the webbing can be filled by activating the second gas generator unit in the remaining filling mode with the gas quantity of the second gas generator unit.

In an extended embodiment, the webbing is filled in the pre-filling mode with a lower gas volume flow and in the remaining filling mode with a higher gas volume flow. The gas volume flow indicates the volume of the gas which flows through a cross-section of a blow-in channel within a unit of time. Due to the lower gas volume flow in the pre-filling mode, a slower pre-unfolding of the tubular webbing portion takes place, whereby the Gurtbandlagen can more easily solve each other. In the residual filling mode, the webbing layers are at least partially spaced apart so that a faster deployment of the webbing section with the higher gas volume flow is possible.

The pre-filling mode with the lower gas volume flow and the residual filling mode with the higher gas volume flow can be represented, for example, by a pyrotechnic gas generator which has a combustion-dependent gas volume flow. In the case of the combustion-dependent gas volume flow, the height of the gas volume flow depends on the quantity of the already burned, gas-generating blowing agent. In one embodiment, the propellant for gas generation for the pre-charge mode burns more slowly, thereby producing gas more slowly, and faster for the remainder of the fill mode, thereby producing gas more quickly. The rate of combustion can be determined, for example, by material properties of the propellant or by the ratio of Surface to volume of the blowing agent can be influenced.

In one embodiment, the first injection channel and the further injection channel and thus the injection point and the further injection point on the webbing merge into one another. A distance between the blower channels goes to zero, so that a partition between the blower channels can be omitted.

Embodiments of the invention will be explained in more detail with reference to the figures. Showing:

1 a schematic representation of an automatic belt with a partially tubular webbing;

2 an enclosure with several Einblaskanälen and a curved support surface in cross section;

3a a cross section through an enclosure with a running in the enclosure tubular webbing;

3b a sketchy grid model of the enclosure;

4a an enclosure having a plurality of injection channels in cross-section and with a flat-folded tubular webbing section extending through the enclosure;

4b the enclosure 4a wherein the tubular webbing portion is prefilled with a subset of the gas of a gas generator;

4c the enclosure 4a wherein the tubular webbing portion is filled with a further subset of the gas of the gas generator.

In the figures and in the description of the figures, the same reference symbols and designations may be used for features having the same function in order to achieve a better overview. If features or designations are shown several times, these are also not necessarily provided with a separate reference numeral for better clarity. This is especially true for a channel 6 especially if it branches in its course. The angles of displayed progressions of channels 6 are exemplary and may vary in another embodiment. The arrows shown in the figures represent a flow direction of a gas from a gas generator 2 in the direction of the tubular webbing section 1a represents.

In 1 schematically the structure of an automatic belt is shown. The automatic belt is a common embodiment for a safety belt with a variable extension length of a webbing 1 . 1a , According to the invention is in 1 the webbing 1 . 1a with a tubular webbing section 1a executed. The webbing 1 . 1a is with a final fitting 13 with a vehicle, for example, on a shell or on a seat of the vehicle attached. A lock tongue 12 is on the webbing 1 . 1a . 1a slidably attached. The lock tongue 12 is when angurten an occupant in a in the 1 not shown buckle inserted and locked, the buckle is also attached to the vehicle. In a belted state forms the tongue 12 a deflection for the webbing 1 . 1a , The tubular webbing section 1a runs on a vehicle-fixed filling place 3 on a gas generator 2 past. The tubular webbing section 1a can from a webbing retractor 11 partially wound or unrolled. When winding or unrolling the tubular webbing section 1a becomes the tubular webbing section 1a at the vehicle-fixed filling place 3 moved longitudinally along its main extension direction. If the gas generator 2 is activated, it fills the tubular webbing section 1a at the vehicle-fixed filling place 3 , wherein at least one Einblassstelle on the webbing 1 . 1a , which are at the vehicle-fixed filling 3 located, the gas of the gas generator 2 through a fabric section of the tubular webbing section 1a flows through it. Such a filling of the webbing 1 . 1a with gas, which is also called inflating the webbing 1 . 1a can be referred to, at different extension lengths of the webbing 1 . 1a respectively.

The tubular webbing section 1a runs in an advantageous embodiment in a belted state over a torso of the webbing 1 . 1a belted inmates. In the area of the upper body, in the case of an accident, the inflated tubular webbing section 1a Protect the occupants particularly well. The vehicle-fixed place of filling 3 lies in a particularly advantageous embodiment in the shortest possible extension of a region of the webbing 1 . 1a , which runs over the upper body of the belted occupant. Thus, a region of the tubular webbing section, which extends over the upper body of the occupant, be filled as directly as possible with gas. A filling of the tubular belt section 1a over the lock tongue 12 and the buckle would be very expensive. When filling a completely tubular webbing over the end fitting 13 In the belted state would the tubular webbing in the area of the tongue 12 squeezed by the deflection so that an inflow of the gas in the behind the lock tongue 12 would be severely hampered tubular webbing section.

In 2 is an enclosure 4 shown with several injection channels in cross section. The tubular webbing section 1a passes through the enclosure, with the right, in 2 expanded part of the webbing portion in the direction of one with the webbing 1 . 1a belted inmates runs. The enclosure has a first injection channel 6.1 , a second injection channel 6.2 and an nth injection channel 6.n in which the variable n is intended to illustrate that the number of injection channels can be extended in other exemplary embodiments. The enclosure 4 still has a bulge 5 in the form of a curved surface.

The course of the first inlet channel 6.1 and the course of the bulge in the extension of the first injection channel 6.1 are matched, so one from the first injection channel 6.1 emerging gas flow in its further course from the bulge 5 streamlined is deflected. The angle between the first injection channel 6.1 and the surface of the tubular webbing section 1a favors that in the webbing section 1a blown gas flows in the direction of the occupant to the right. This also causes a filling of the part of the webbing section 1a favors, which rests against the occupant, for example, on the upper body. The cross section of the first inlet channel 6.1 is the largest cross section of the blower channels 6.1 . 6.2 . 6.n , so that the largest part of the gas of the gas generator 2 for filling the webbing section 1a through the first injection channel 6.1 flows.

The angle between the second injection channel 6.2 and the surface of the tubular webbing section 1a in the folded state is designed such that the lower layer of the webbing portion when filling the Gurtbandabschnittes due to the Bernoulli effect by the through the second injection channel 6.2 escaping gas in the lower part of the bulge 5 is pulled. The upper layer of the webbing section 1a is pulled down less so that there is a separation of the lower and upper layer of the webbing section 1a comes. The separation of the layers is favored by the above the second blow-in channel 6.2 downwardly curved part of the bulge. If the webbing 1a when filling it applies this downwardly curved portion of the bulge, there is a relative movement between the lower and the upper layer of the webbing portion, which favors a separation of the lower and the upper layer from each other. A better separation of the layers favors the filling of the tubular webbing section 1a with the gas of the gas generator 2 ,

The nth inlet channel 6.n stands in this embodiment representative of other injection channels. For example, another injection channel may affect a shape of the inflated webbing portion. Such influencing may be advantageous, for example, for a longitudinal displacement of the tubular webbing section 1a within the enclosure 4 to improve. That from the nth injection channel 6.n escaping gas hits the side of the webbing section 1a , This results in an additional lateral filling of the webbing section 1a ,

3a schematically shows an embodiment of an enclosure 4 which the webbing 1 . 1a at the vehicle-fixed filling place 3 embraces. The enclosure 4 is shown in cross-section. The tubular webbing section 1a passes through the enclosure 4 therethrough. The enclosure 4 has a channel 6 on, by which when filling the webbing 1 . 1a Gas is flowing. At the point where that through the channel 6 flowing gas on the tubular webbing section 1a meets, there is a Einblassstelle on the webbing 1 . 1a wherein the gas passes through the fabric section of the tubular webbing 1a flows through at the injection point. The enclosure 4 has a bulge 5 on, with the bulge 5 in the embodiment of the injection point in the direction of an outlet opening of the enclosure 4 , which is in the direction of the occupant, widens. The bulge 5 leaves a widening of the tubular webbing section 1a too, which is when inflating the tubular webbing section 1a results.

In 3b the device is off 3a shown in a grid model, wherein the tubular webbing section 1a not shown. In 3b it can be seen that the channel is 6 at the filling place 3 in a first injection channel 6.1 and another, second injection channel 6.2 and a third injection channel 6.3 up to an nth injection channel 6.n branches, where n stands for the total number of single-jet channels. The total number of subchannels is in 3b with example 4 shown. Through each of the blow-in channels 6.1 to 6.n goes on filling the webbing section 1a a separate fraction of the gas of the gas generator 2 ,

4a shows an enclosure with a running through this Gurtbandabschnitt 1a in cross section. The enclosure has a first injection channel 6.1 , a second injection channel 6.2 and a third injection channel 6.3 , as well as an nth injection channel 6n on. The blow-in channels are extensions of a channel 6 which the gas of the gas generator 2 to the webbing section 1a leads.

4b shows the enclosure 4 with the webbing section 1a out 4a , wherein the webbing section 1a in a pre-charge mode with a subset of the gas of the gas generator 2 through the injection channels 6.1 . 6.2 . 6.3 . 6.n is filled. This partial filling of the webbing section 1a at least partially separates the layers of the folded tubular webbing section 1a ,

In 4c It is shown that the pre-filled webbing section in a residual filling mode with a further subset of the gas of the gas generator 2 is filled. By pre-filling the webbing section 1a , what a 4b is shown, the remaining filling of the webbing section 1a improved, so that the remaining filling can be performed with a higher gas flow rate.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 2008048 A1 [0002]
• DE 19821996 A1 [0003]
• DE 102006003794 A1 [0004]

Claims (9)

Safety belt for a vehicle, comprising a gas generator ( 2 ) gas-filled at least partially tubular webbing ( 1 . 1a ), wherein the gas generator ( 2 ) at a vehicle-fixed filling location ( 3 ) the webbing ( 1 . 1a ) in its tubular webbing section ( 1a ) at least one Einblasstelle the webbing ( 1 . 1a ) through a fabric section of the tubular webbing section ( 1a ) can be filled with gas, characterized in that the webbing ( 1 . 1a ) at the injection point through a first injection channel ( 6.1 ) with a first fraction of the gas of the gas generator ( 2 ) and at another injection point by a further injection channel ( 6.2 ) is filled with a further fraction of the gas. Safety belt according to claim 1, characterized in that the fraction of the gas due to the flow resistance of the injection channel ( 6.1 ) is predetermined. Safety belt according to one of the preceding claims, characterized in that an angle between an inflow direction of the gas in the webbing ( 1 . 1a ) and a surface of the webbing ( 1 . 1a ) at the filling location ( 3 ). Safety belt according to one of the preceding claims, characterized in that Einblasstellen on opposite sides of the webbing ( 1 . 1a ) are provided. Safety belt according to one of the preceding claims, characterized in that at least one angle between an inflow direction of the gas into the webbing ( 1 . 1a ) and a surface of the webbing ( 1 . 1a ) at the filling location ( 3 ) is set so that during the filling of the webbing ( 1 . 1a ) with gas the webbing ( 1 . 1a ) by the Bernoulli effect at least partially at the filling ( 3 ) is sucked. Safety belt according to one of the preceding claims, characterized in that the strap ( 1 . 1a ) at the filling location ( 3 ) of a supporting surface, which is depicted as a free-form, against one during the filling of the belt ( 1 . 1a ) acting gas pressure is supported. Safety belt according to one of the preceding claims, characterized in that the strap ( 1 . 1a ) in a pre-filling mode with a subset of the gas of the gas generator ( 2 ) and then the webbing ( 1 . 1a ) is filled in a residual filling mode with a further subset of the gas. Safety belt according to claim 7, characterized in that the webbing ( 1 . 1a ) is filled with a lower gas volume flow in the pre-filling mode and with a higher gas volume flow in the remaining filling mode. Safety belt according to claim 7 or 8, characterized in that the first injection channel ( 6.1 ) and the further injection channel ( 6.2 ) and thus the Einblasstelle and the other Einblasstelle into each other.

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