DE2218253B2 - Safety harness webbing - with multi-step give provided by different strength warps - Google Patents

Abstract

Webbing has a first warp of medium strength high tensility and >=2 other warps selected from yarn of low strength low tensility, medium strength medium tensility, or high strength high tensility, relative to the first warp yarn. The first warp constitutes a first texture together with weft yarn of medium strength high, tensility, the second and third warps constituting a second texture together with the weft. The warps will not break or elongate under a load of 200-1100 kg after which the second and third warps break progressively by the first texture, allowing the webbing to elongate without load increase and preventing violent recoil after removal of load.

Description

The invention relates to a safety belt with graduated compliance, which consists of threads of different strength and a multi-chain fabric of different elongation.

These seat belts are intended to prevent the occupants of vehicles or aircraft in the event of a collision The mechanical loads that occur in the process protect in particular against injuries caused by secondary collisions with the internal structure of the vehicle. A corresponding application as parachute harnesses and seat belts for workers at greater heights is also provided.

A belt of the type mentioned at the beginning is already known as the state of the art (DT-OS 19 10 288). Be This seat belt is used with a multi-chain one; Fabric in which each chain incorporates a different one has processing and interweaving. Here a chain in its extensibility is equal to zero, around a primary one Resistance to stress first. Furthermore, this seat belt has two layers, which « a combination of different thread layers. This inevitably results in this belt being a has a relatively large thickness. However, through this great thickness, the handiness in the condition becomes this; Belt deteriorated and also the space requirements increased, for example when rolling up the belt.

A belt strap for füi is still state of the art Seat belts known (DT-OS 14 81962), the fabric from a combination of different! Yarns with different elongation properties are produced so that the elongation properties de: Tissue can change with a change in load. The change in the stress is nui compensated for by the stretch properties of the tissue.

Furthermore, belts are known which, using two types of warp thread with different types rather elasticity are produced (US-PS 34 64 459). Be With this webbing, there is no mutual action between the two types of warp thread, i.e., de The warp thread of the core and the other warp thread remain independent of one another in their function.

In another seat belt, which belongs to the state of the art, a binding medium is fü two types of warp thread arranged between these unc enables a correlative function between these ci two types of warp thread with different elasticity when an impact occurs (US Pat. No. 3,148,710). This* However, the type of binding increases the strength or the thickness of the seatbelt, which is especially dam

is disadvantageous. if the belt is used in a retrieval device is drawn in, which must then be very large. In addition, the supple wedge suffers the seat belt.

The object of the present invention is now> in creating a belt of the type mentioned at the outset, the warp thread of which withstands a certain initial load, while a further increase in load to an elongation and intermittently repeated breaking or tearing of certain warp threads leads, so that a further increase in the force acting on the belt and also a violent hurling back after burial of this force caused by the torn !. Warp thread is prevented.

This object is achieved according to the invention by a first warp thread of medium strength wedge and high extensibility, by at least a second and a third warp thread with, in contrast, low strength and low extensibility, by a warp thread of medium strength and medium extensibility and by a warp thread of high strength and low extensibility, wherein the first warp thread and weft thread of medium strength and high extensibility form a woven structure, and wherein the / wide and third warp threads and the very,! '!. ¹ .;!; !! Form a / wide 2s weave structure, both Wcbsuukmren are connected to each other and wherein the first, second and third warp thread only break when the belt is loaded from 200 to 1100 kg and have a very low elongation compared to the increase in load; by gradually and repeatedly tearing the / wide and third warp threads, supported by the first type of weave, until the elongation after the load reaches a predetermined value and the belt can be extended without increasing the load. Due to the correlative effect of the first and second weave, it remains in its shape after the load has ceased and is given a graduated flexibility with an approximately parallelogram-shaped load-elongation curve.

This has the advantage that a seat belt is in the form of a relatively thin, dense belt fabric is created, which has a certain required breaking strength and a snap back when unloading prevented by absorbing impact energy. With the thin and supple one according to the invention The belt also has the advantage of requiring little space with a mechanical retraction device and ease of use.

Further features of the invention emerge from the sub-claims.

The invention is described in more detail below with reference to exemplary embodiments shown in the drawing. In the 7> ηηιιημ / eigi

Fig. I a Lan * v.hnitt through the crfindtingsgemäß Tissue.

Fig. 2 is a perspective view of the belt fabric.

F i g. 3 the binding or weaving of the belt,

4 shows a graphical representation of the relationship of lii-laMiing and stretching in one Seat belt according to the invention.

F i g. 5 shows a graphic representation of the relationship / wipe the strength and elongation of the yarn used in the belt according to the invention,

F i g. b a graphic representation of stress (15 and stretching a seat belt with a further embodiment of the belt,

Fig. 7a shows the relationship between the load and the elongation when the belt is used as a Hip belt,

F i g. 7b shows the relationship between the load and the elongation when using the belt as Shoulder strap,

F i g. 8a the relationship between the load and the elongation of the known belt as a hip belt,

Fig.8b loading and elongation of the known Strap as shoulder strap,

9 shows a three-point belt as a combination of the Hip belt with the load-elongation curve according to FIG. 7a and the shoulder strap with the load-elongation curve according to FIG. 7b,

10 shows a three-point belt as a combination of the known belt with the stress-strain curve according to Fig.8a and the known shoe strap with the stress-strain curve according to FIG. 8b.

F i g. 11 the relationship between the acceleration and the time on the floor of a vehicle in an impact test.

F i g. 12 the connection between the accelerations and the time in the head of a dummy an impact test,

13 shows the relationship between the load at anchoring point 7 of the shoulder strap and the Z <_it during an impact test and

14 and 15 each show a further embodiment the invention.

The warps 11, 12, 13 and 14 and wefts 15 in the F i g. I to 3 are structured as follows:

Warp thread 11:

Medium strength and high elongation. Warp thread 12:

Low strength and low elongation. Warp thread 13:

High strength and low elongation. Warp thread 14:

Medium strength and medium elongation. Weft thread 15:

Medium strength and high elongation.

According to FIGS. I and 2, the warp thread 11 runs over two weft threads 15 and then under the next two warp threads 15, so that you have a first weave so-called twill weave (2 above / 2 below).

The warp threads 12, 13 each consist of several parallel threads and run alternately over and under the weft thread 15, so that the second weave is a plain weave. The warp thread 14 runs alternately under and over the weft thread 15 / wipe each warp thread 11 and forms part of the / wide weave, the plain weave.

F i g. 3 shows the weave of the weave described. In this weave diagram, the warp threads run ir Longitudinal direction and the weft threads across it. White squares show the places where the warp threads overlap Weft threads run, black squares the places where warp threads go through under weft threads.

A yarn for the warp thread 12 of the ncn weave described above is polyamide fiber yarn, the elasticity of which by boiling in hot water at 95 to 100 ° ( was increased by about 10% during 25 to 30 minutes. If necessary, the same as the edited one can be used Warp thread II next to the warp threads 12, 13 and 14 fürdi second weave can be used.

Instead of a single thread, two up for threads can be used together in a section of weave fii

the warp thread 12 can be used.

In the following the in the F i g. 1 to 3 shown weaves.

Embodiment 1 _s

A vehicle seat belt with a width of 50 mm was shown in FIG. 3 from warp threads 11 to 15 woven.

Warp thread 11:

188 threads of a polyester synthetic fiber of medium strength and high elongation of 840 / 96-1 / 2S-140 turns / m, i.e. two threads of 96 fibers each, a total denier of 840 and S-wire, with 140 turns per meter (in Fig. 5 = Γ500).

Warp thread 12:

100 threads of a polyester synthetic fiber of low strength and low elongation of 250 / 24-1 / 2S-75 turns / m (in FIG. 5 = R 120).

Warp thread 13:

10 threads of a polyester synthetic fiber of high strength and low elongation of 1000 / 250-1 / 1S-100 Turns / m (in Fig. 5 = P500).

Warp thread 14:

10 threads of a polyester synthetic fiber of medium strength and medium elongation of 1000 / 250-1 / IS-100 turns / m (in Fig. 5 = /? 620).

Warp thread 15:

Thread size 18. i.e. 18 threads on 25.4mm one Polyester synthetic fiber of medium strength and high elongation of 840 / 96-1 / 2S-100 twists / m (in Fig. 5 = Γ500).

When the belt is stretched, the ratio of the belts acting on the belt was increased Load and its elongation examined. The elongation after stopping the exercise was also tested. The result is shown in FIG. 4, the ordinate being the load increase and the abscissa being the Extension of the strap shows.

It follows from the illustration that the belt was lengthened linearly by 7 to 8% under a load of less than 400 kg. From point A onwards, the load was absorbed by the belt. At point B the elongation reached about 25%. The assumed function of the warp threads U to 15 between points A and B is set out below:

At point A , the warp thread 12 of low strength and low elongation first breaks. Then the warp threads 13 and 14 tear apart from the warp thread 11 when the load exceeds their strength and elongation. When the load reaches point A , primary breaks on the warp threads 12,13,14 take place at the same time fczw. on each other. If the load increases further, the first weave with the warp thread 11, which interacted loosely with the second weave with the warp threads 12, 13, 14, interacts more closely with this weave.

In other words, this means that the weft thread 15 of the first weave, so far only in loosely Engagement with the warp thread of the second weave, the already broken or not yet broken warp thread There is strong support due to the stretching of the warp thread 11, which is the load and / or Tension of the warp thread 11 has absorbed, due to the -tlirekien load, over different times The other warp thread breaks, so that there is a strong interaction between the first and second weave comes about. As a result, the warp thread, which is already the primary break, is loaded again was exposed over the medium of the first weave, so that a secondary and tertiary breakage of the warp thread occurs one after the other, with the result that the increasing load on the entire belt is effective is absorbed.

Although the warps 12, 13 and 14 break gradually and repeatedly, the warp 11 of the first weave does not break. The belt as a whole is subject to plastic deformation according to curve AB in I-i g. 4 and thereby absorbs energy.

The value of the load at point A can be determined by choosing the strength, elongation and number of individual threads of the warp threads 12, 13, 14, in particular 12.

If the elongation exceeds 25%, the belt will lengthen as the load increases. At point C, when the load reaches 1130 kg, the elongation exceeds 40%. After the load has ceased, the belt shortens to about point D. However, since a large number of the warp threads have already torn, the shortening or shrinkage due to the resistance between the warp threads is extremely small, which at the same time has strong rebound forces and the resulting dangers for diminished to humans.

By choosing the number of warp threads per unit of length and the number of weft threads per unit of length, the approximately straight section between points A and the curve in FIG. 4 set. It is also advisable to make the belt in such a way that the section between B and C where the flat section ends and the curve rises again, at the section between B and E, remains horizontal and the curve returns to section ED after the load has ceased.

In the embodiment described, the warp thread 11 and the weft thread 15 form a first weave Twill fabric. However, the same properties can also be achieved by using the twill weave replaced by a plain weave and also if the second weave with the warp threads 12, 13 and 14 as well how the first twill weave was made.

You can also use straps for seat belts, especially shoulder straps, by choosing the The specified value for the initial breakage of the warp threads in the range of 200 to 800 kg, with the bond has a greater elongation in relation to the increase in load, until the elongation is 20 to 30% reached above the specified value.

According to FIG. 6, a peak load absorption is provided before the predetermined value of the load by one increases the number of warp threads 12,13 and 14, the in embodiment 1 forming the second weave, and by making the warp thread 11 of the first weave conveys a comparatively great tension. This peak load absorption reduces the impact on impact acceleration acting on a person's head.

If, as mentioned, the warp thread 11 is woven at a higher tension, the broken warp thread remains stretched under pressure by the first weave at the same time as the initial tear, so that the The warp thread does not slip into the first and second weave. This means that the broken warp thread through the first weave is supported under pressure and counteract the following load immediately after the break can.

Embodiment 2

A belt of the same width as Embodiment 1 was made in the same weave using the warp thread It to 15, which goes to aiii the number of threads are identical to this embodiment. The belt, however, was being used greater tensile strength (300 to 350 g / thread) for the warp thread 11 than in embodiment I. (150 to 200 g / thread) was the case.

Warp thread 11:
Warp thread 12:
Warp thread 13:
Warp thread 14:
Weft thread 15:

188 threads.
180 threads.

18 thread.

18 threads.
Thread measure
25.4 mm.

18, i.e. 18 threads

The relationship between load and elongation was examined, as was the elasticity according to Stop the load (Fig. 6). Own the webbing excellent properties for use as a seat belt and preferably as a shoulder belt.

Although in the above-mentioned embodiment warp thread 11 and weft thread 15 of the first weave with Twill weave are carried out, one obtains the same properties as in embodiment 1, also with Plain weave instead of twill weave and even if the second weave is with the warp thread 12, 13 and 14 is woven as in embodiment 1 with a twill weave.

The belt stand according to this embodiment is suitable! opt for seat belts, especially shoulder belts, by adding one chooses the given value of the load between 200 to 800 kg. The warp thread should be in proportion have greater elongation for the load, until the elongation according to the specified value is 20 to 30% achieved.

A seat belt with the belt strap according to the invention as a shoulder and / or hip belt has a excellent energy absorption.

In the following another embodiment of a three-point belt is described in which the Belt strap according to embodiment 1 in the shoulder belt and another belt strap according to the invention as a hip belt is used.

Embodiment 3

Belt strap for seat belts with the same width as embodiment 1 and with the same type of weave.

The load-elongation curve of the binding is shown in FIG. 7a.

Warp thread It: polyester synthetic fiber, 160 threads.
Warp thread 12: polyester synthetic fiber, 40 threads.
Weft thread 15: polyester synthetic fiber, thread size 18, ie 18 threads on 25.4 mm.

9 shows a three-point belt A with a binding according to embodiment 3 for the hip belt 21 and with a binding according to the load-elongation dependency according to FIG. 7b for the shoulder belt 22. FIG. 9 also shows a buckle 23 and anchors AnA.AnA'and AnA ".

FIG. 10 shows a three-point belt B with the known belt strap with the properties according to FIG. 8b. The buckles 26 and the anchorages AnB, -4nß'and AnB "can be seen.

During an impact test, a vehicle with a three-point belt A or β hit a solid barrier at an impact speed of 47 km / h. The acceleration effective on the floor of the vehicle is shown in FIG. II.

The accelerations acting on the head of the dummy held by the belt A are shown by the solid line in FIG. 12. The dashed line in this figure shows the accelerations acting on the head of the dummy which was held by the belt.

The loads on the anchorages AnA and AnB (FIGS. 9 and 10) of the belts A and β are shown in FIG. 13 with a solid or broken line. The maximum loads were found on the anchorages AnA and AnB of straps A and B with 678 and 868 kg, respectively. The following table shows the loads on the anchorage AnA ' on the vehicle center side of the shoulder belt A, the anchorage AnA "on the opposite side, the anchorage AnB' on the vehicle center side of the belt B and the anchorage AnB" on the opposite side .

AnA '= 981 kg AnA "= 664 kg.

AnB '= 882 kg. AnB '= 534 kg.

This experiment also shows that the bond according to the invention gives excellent energy absorption.

The belt strap for the shoulder strap of the three-point belt is preferably min greater elongation in Ratio to the load increase selected until the elongation after a given value of the initial load 20 to 30% achieved. The predetermined value becomes the range of 200 as in Embodiments 1 and 2 limited to 800 kg (Fig. 7b, 8b).

The binding for the hip belt of this three-point belt is preferably with greater elongation in proportion chosen to increase the load until the elongation reaches 10 to 20% after a given value of the load, the specified value being between 500 and 1100 kg (Fig. 7a, 8a).

In addition, the belt according to Embodiment 2 was experimentally used as the shoulder belt of the three-point belt used, with just as satisfactory result as in the above experiment.

Fig. 9 shows an embodiment of the three-point belt. The same results are obtained when applied for a double shoulder belt and a seat belt in the form of an inverted Y according to FIG. 14 and 15th

14 and 15 the hip belt 27, 29 according to embodiment 3 and the shoulder belt 28, 30 according to embodiment 1 or 2, which form a seat belt C, D, are used. The anchoring AnC, AnC, AnC ", AnD. AnD 'and AnD" can also be seen.

In addition 6 sheets of drawings

509 582/23:

Claims (12)

Patent claims: 1. Seat belt with graduated flexibility, which is made of threads of different strength and consists of a multi-chain fabric of different elongation, characterized by a first warp thread (11) of medium strength and high extensibility, through at least one second and third warp thread with, in contrast, lower strength and lower extensibility (12), through a medium strength warp thread and medium extensibility (14) and a warp thread of high strength and low extensibility (13), wherein the first warp thread (11) and weft thread (15) are one of medium strength and high extensibility Websirukuir form and the second UAd being the third The warp thread and the weft threads form a second weave structure, both weave structures together are connected and wherein the first, second and third warp thread only when the belt is loaded from 200 to 1100 kg tear and very little elongation compared to the increase in Exhibit load; by gradually and repeatedly tearing the second and third warp threads, supported by the first weave until the elongation after the load has reached a predetermined value achieved and the belt can be extended without increasing the load, due to the correlative effect of first and second weave remains in its shape after removal of the load and one graduated compliance with an approximately parallelogram-shaped load-elongation curve. 2. Belt according to claim!, Characterized in that that at a given load between 200 to 800 kg of the Keufaden a large elongation in Compared to the increase in load, the elongation is 20 to 30%. 3. Belt according to claim I, characterized in that at a predetermined load between 500 up to 1100 kg the warp thread has a large elongation compared to the increase in load, whereby the Elongation is 10 to 20%. 4. Belt according to claim 1, characterized in that the first weave with a twill weave and the The second weave is plain weave. 5. Belt according to claim 1, characterized in that both types of weave carried out with a plain weave are. 6. Belt according to claim 1, characterized in that both types of weave are designed with a twill weave are. 7. Belt according to one of the preceding claims, characterized in that the volume of the second and third warp thread and the tension of the first warp thread are selected to be comparatively large, with the second and third warp thread at a load that is greater than the predetermined value gradually and repeatedly ze ^r risscn (Fig.6). 8. Belt according to claims 2 and 7, characterized by the use as a school belt. 9. Belt according to claim 3, characterized by the use as a hip belt. 10. Belt according to claim 9, characterized by the use as a Hiiftgurt, wherein the belt is a has less stretch than the shoulder strap. 11. Belt according to one of the preceding Claims, characterized in that the volume of the third warp thread and the tension of the first warp thread can be increased, with a load that is greater than the predetermined Wen is between 200 to 800 kg, the warp thread breaks, and so that the load with the value of the specified Load matches, support », through the first weave until the elongation is 20 to 30%, se that the belt can lengthen without further increasing the load. 12. Belt according to claim 8, characterized by the use as a double shoulder belt, with each a strap goes over the right and left shoulder.