DE2012696A1 - Parachute - Google Patents

Description

Patent attorneys'
Dr. Ing.Walter-Abitz
Dr. Dieter F. Morf
Dr. Hans-A. Browns
2l

March 17, 1970 P-5 87

IRVIN AIR CHUTE, LIMITED: 479 Central Avenue, Port Erie, Ontario, Canada

Parachute

The. Invention relates to improved parachute caps »

When using the parachutes common today, most of which have a nylon canopy with an air permeability of 80 to 120 cubic feet per square foot of fabric per minute (24 to 37 m ³ / m ² min.) At 12.7 mm water column , two problems arise when a crew disembarks from an aircraft: dangerously high opening heights of the parachute at high exit speed and inadmissibly long opening times of the parachute when disembarking at low altitude at low speed, in which case the parachute may open before the impact the soil does not fully unfold. It is therefore an essential object of the invention to provide a parachute canopy with relatively low air permeability when exiting at low speed and at relatively high speed

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Air permeability when exiting at high speed to develop.

Briefly, the invention relates to equipping at least part of a parachute canopy with stretch fabric. It is known to temporarily reduce the air permeability of a parachute canopy by around 9% by using to increase tear-resistant threads of stretch yarn, as described in US Pat. No. 3,032,072. Such a one However, a parachute canopy made of tear-resistant stretch yarn did not have the properties required for high such as for low exit speeds.

The invention also provides a parachute canopy in which at least a part is made of stretch fabric and a substantially balanced elongation between the stretch fabric panels and the main seams takes place. '

Further features and details of the invention result from the following description and the associated drawings, which show the following:

1 shows a partial plan view of a parachute canopy constructed according to the invention;

Fig. 2, 3 and U enlarged sectional views taken along the Lines 2-2, 3-3 and 4- * * of Figure 1;

Fig. 5 is a partial plan view of a main seam according to the invention assembled parachute canopy;

6 shows an enlarged partial section along the line 6-6 in FIG. 5;

7, 8, 9 graphs of the behavior of the more common

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Parachute caps and caps according to the invention.

The drawings show preferred embodiments of the invention again; like parts are congruent in all figures denotes »A parachute canopy A according to the ■ Invention consists of a series of wedge tracks B, which are connected to one another by main seams C; there is each wedge track from a plurality of fields D, E, F and G, which are connected to one another by transverse seams H. can and each cap A can have a venting seam J, an edge seam K and carrying lines L «

• The term stretch fabric is used in this description to understand a fabric in which warp or weft or both are made of stretch yarns or elastic yarns. ·,

Ordinary tissue is the name given to a tissue that is not stretchable, i.e. a fabric that does not have any stretch yarn or elastic yarn or at least minimal amounts of stretch or elastic yarn in the construction of the subject-matter of application is used.

The stretch fabric preferably has virtually nonexistent Tensile load an air permeability of 0 to

3 2 UO cubic feet per square foot per minute (0 - 12.2 m / m .min) at 0.12 mm WS pressure difference and an air permeability with practically maximum pull without permanent change in shape from 600 to 1000 cubic feet per square foot per minute (183 to

3 2
305 m / m min) at 12 mm water column pressure difference. These limits suggest the use of a unidirectional fabric, that is, a fabric in which the stretch yarns are either warp or weft while the other (weft or warp) is conventional yarn.

Under certain conditions, for example when exiting

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At extreme heights or, in some cases, when loads are dropped, values for air permeability can be used, for example with maximum pull without permanent change in shape of 3000 cubic feet per square foot per minute at 12 mm WS

3 2

Pressure difference (914 m / m .min.) Are required} in this In this case, a bi-directional stretch fabric can be used, i.e. a stretch fabric in which The warp and weft are made of stretch yarn.

Since both weight and space requirements are critical sizes Given parachute construction, it is assumed that the preferred construction according to the invention is from a Stretch fabrics that have primary unidirectional stretch and are less bulky than a fabric with stretch effect in all directions, and in which the stretch effect through the use of stretch ga: instead of elastic yarn, which saves weight.

A stretch fabric that we have found useful has 125 to 135 threads of 30 denier high-strength nylon in the warp 66 per inch and in the weft 90 to 100 threads of 30 denier medium strength counter-twisted (false twist) nylon per inch on. A standard 28 ft (8.5 m) diameter parachute canopy made of ordinary fabric is often called the standard parachute C-9, and this term shall be used hereinafter.

According to Fig. 1, as Form I of the invention, only the field D of each fabric web B is made of stretch fabric, while the fields E, F and G consist of ordinary fabric ; Form II has panels D and E of fabric web B made of stretch fabric, while panels F and G consist of ordinary fabric; according to form III, the fields D, E and F of each fabric web 3 consist of stretch fabric and the field G of ordinary fabric; Finally, according to Form IV, all fields of the length of fabric are made of stretch fabric.

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In Form I, the ratio of stretch fabric to ordinary is Fabric in such a way that the area of stretch fabric, because of its small size, has the opening force at high speeds and the opening time at low speeds is only slightly compared to a standard screen C-9 influenced.

Form II has a concave curve showing the relationship between opening force and jump speed (cf. Fig. 7), that is, a marked improvement over a standard C-9 screen up to one speed consists of approximately 220 knots; beyond that speed forces are generated that are greater than those of a standard parachute C-9 lie.

Form III has a curve with a convex curvature for the Relationship between opening force and jumping speed on (Fig. 7), from which it follows that the reduction The opening force is more noticeable compared to a standard parachute C-9, the greater the jump speed is. Below is a tabular comparison between Form III and a standard C-9 parachute;

speed C-9 force ■ Form III reduction (Node) 2400 2U00 % 120 3200 3000 0 180 UlOO 3200 6.6 210 U900 3700 28.1 230 32, U

At speeds below 120 knots, the Form III has slightly higher opening forces than the standard parachute C-9, however, at such low take-off speeds the opening speeds are not so great that any Problems arose.

The curve divisions in Figures 7, 8 and 9 provide one

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m Q m

Basis of comparison between Forms II and III and the standard parachute C-9.

The curves of FIGS. 7, 8 and 9 were determined by Dropping a dummy weighing 250 pounds (113 kg) in 1500 feet (457 m); the legend to Fig. 7 also applies to the 'Fig. 8 and 9. Examination of these curves shows that Form III evidently produces optimal results in so far as not only lower opening forces at high speeds (Fig. 7) but also shorter opening times (Fig. 8) and shorter filling times (Fig. 9) at lower speeds offered, i.e. that this form can also be used for jumping at low speed and lower Height is more effective. Since the shape III apparently gives optimal results, the seams are on it according to the Figs. 2, 3, H and 6 are shown.

Dio Form IV results in lower opening forces at high ones Speeds, but the increasing air permeability at the edge seems to hamper the correct filling. That will This was helped by an area made of ordinary fabric length of the edge of the parachute canopy, which is otherwise made of stretch fabric consists; as a result, the umbrella opens faster, especially at low speeds.

The standard parachute consists of a number of lanes with four fields each, and this shape is shown here and described. The essential criterion is of course the ratio of stretch fabric to ordinary Fabric, regardless of the special construction of the parachute canopy, i.e. a canopy with Form III practically 75% stretch fabric versus 25% ordinary fabric.

Furthermore, the invention -ei various other types of parachutes, band brake parachutes, Ringapaltschir men uew. use. The invention is also intended for persons *

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as apply to cargo parachutes.

As already mentioned, there is one that we have found useful Stretch fabric made from a stretch yarn warp and a conventional, practically inelastic weft. We prefer to cut the fabric at an angle to get fields where the warp runs diagonally across the field, like through the arrows in Fig. 1 indicated. In this way, both the panels of stretch fabric and the Move fields of ordinary fabric in a given path. The warp direction is preferably below practical 45 ° with respect to the main seam, and the chain of corresponding fields of adjacent tracks run essentially inclined at 90 ° to each other. Such a directional cut and such an arrangement causes more uniform loading on the main seams.

As can be seen in FIG. 2, there is no complete departure from the Structure of the transverse seams with regard to the connection of the stretch fabric of the field F with the usual fabric in the field G through stitches 10 required; as Fig. 3 shows, results also no complete deviation from the usual structure of the transverse seam when connecting the stretch fabric of the field D with the stretch fabric of the field E by stitches 11} and how As can be seen from Fig. 4, an essentially common one becomes EntlÜfturigsraum for connecting the stretch fabric of the field D with a tape 12 by stitches 13 applied.

The structure of the main hem H can be seen in FIGS. 5 and 6, for which fields of adjacent strips can be folded around a suspension line L and connected to one another, for example, by stitches It. The edge K can be provided with a reinforcement 15 and with reinforcement stitches 16 for fastening the suspension lines L to the edge.

In a common parachute construction, the main seam means that the main lines are generally shorter than the length of the seam.

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so that the opening forces are transmitted via the support net and not via the main seam. When using Stretch fabrics for parachute construction, we prefer the use of suspension lines that are longer than the main hem to create a balanced elongation between the Stretch fabric fields and the main hem. This structure also enables us to use lighter suspension lines to use because they transmit lower forces have than the suspension lines in common constructions.

The shape, size and arrangement of the individual elements described and illustrated here can be changed in many ways without departing from the scope of the invention; The invention will ined by the following claims de f.

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Claims (17)

P-587 March 17, 1997O Patent claims: / 1·. ! Parachute with a cap, characterized in that the main braking surface ^ of the cap at least partially Stretch fabric is made. 2. parachute with cap, characterized in that at least 75% of the fabric surface of the cap is made of stretch fabric. 3. Parachute with one of a number of lanes with several Fields of the existing cap, characterized in that at least some webs have at least one fold made of stratoid aufwoiqon. . Parachute according to one of claims 1 to 3, characterized in that; that the stretch fabric is a primary stretch in one direction. 5 · Parachute according to one of claims 1 to 3, characterized by * indicates that the stretch fabric has stretch on all sides. 6. Parachute according to claim .3, characterized in that the cap fields of stretch fabric with primary stretch in a direction that is diagonal across the field " ⁹ '00 98A0 / U-2 4. 7. Parachute according to claim 6, characterized in that the direction of the primary stretch with the direction the weft threads of the stretch fabric match 8. Parachute according to claim 6, characterized in that the direction of the primary stretch at practically 45 ° an adjacent radial hem. 9. Parachute according to one of claims 1 to 3, characterized in that that the stretch fabric has an air-permeable 3 2 speed from 0 to 12.2 m / m 12 mm WS pressure difference. 3 2 speed from 0 to 12.2 m / m .min in the draft-free state below 10. Parachute according to one of claims 1 to 3, characterized in that the stretch fabric has an air permeability at maximum tension without permanent change in shape of 183 to 305 m ³ / m ² .Min at 12 ram V7S pressure difference. 11. Parachute according to one of claims 1 to 3, characterized in that that the stretch fabric has an air-permeable ■ 3 2 0 to 12.2 m / m .Min in the tension-free state below 12 mm WS pressure difference and an air permeability at maximum tension without permanent change in shape of 18 3 to 305 m ³ / m ² .Min bä 12 mm WS pressure difference. 12. Parachute according to one of claims 1 to 3, characterized in that the stretch fabric has a warp of practically 125 to 135 threads of actually inelastic yarn per inch and a weft of EO to 100 threads of stretch yarn per inch. - 10 - 0098A0 / U2A 13. Parachute according to one of claims 1 to 3, characterized in that the cap has main seam with attached carrying lines and that the length of the carrying lines, measured from the edge to the tip of the canopy, is greater than the length of the main seam " IU. Parachute with one of a number of lanes with several Fields existing cap, characterized in that at least the panel of each panel at the top of the cap is made of stretch fabric. 15. Parachute according to claim. 14, characterized in that that each panel consists of panels of stretch fabric such that practically 75% of the fabric area of the panel consist of stretch fabric. 16. Parachute according to claim 15, characterized in that at least one field of the web at the edge of the cap consists of inelastic fabric and the area of the inelastic fabric of each panel is practically 25% of the fabric area of the train. 17. Parachute according to one of claims 14 to 16, characterized characterized in that the stretch fabric has a primary stretch in one direction. 18. Parachute according to one of claims 14 to 16, characterized characterized in that the stretch fabric has all-round stretch. 19 «Parachute according to one of claims IU to 16, characterized 0098 40 / U2 U characterized in that the fields of the stretch fabric each have a primary stretch in one direction, which runs diagonally through the field 20. Parachute according to claim 19, characterized in that that the direction of the primary stretch is in the direction of the weft threads of the stretch fabric * 21 «Parachute according to claim 19, characterized in that ψ that the fields of the stretch fabric of a certain The web have directions of the primary stretch that are practically parallel to each other , 22 »Parachute according to claim 19, characterized in that the direction of the primary ^{stretch runs practically US 0} ge against the radial hem of the track. 23 · Parachute according to one of claims IU to 16, characterized characterized in that the stretch fabric has an air 3 2 Permeability from 0 to 12.2 m / m. Min in practically draft-free State below 12 mm WS pressure difference has 24 * parachute according to one of claims 14 to IS, characterized characterized that the stretch fabric has an air permeability with practically maximum tension without lead 3 2 Change in shape from 183 to 305 m / m. Min at 12 mm WS has pressure difference. 25 «Parachute according to one of claims IU to 16, characterized characterized in that the stretch fabric has an air - 12 - 009840 / U2A 20-2696 3 2 Permeability from .0 to 12.2 m / m .min in practically draft-free State below 12 now WS differential pressure and air permeability with practically maximum draft without 3 2 permanent change in shape from 183 to 305 m / m. Min 12 mm WS pressure difference. 26. Parachute according to one of claims IU to 16, characterized characterized in that the stretch fabric is a warp of practically 125 to 135 threads of practically inelastic Yarn per inch and a weft of 90 to 100 threads of stretch yarn per inch. 27. Parachute according to one of claims 14 to 16, characterized characterized in that the cap has radial bands to which suspension lines are attached, and that the suspension line length, measured from the edge to the tip of the cap, is greater than the length of the radial bands. 28. Parachute with a canopy, characterized by a braking surface, the fabric surface of which is practically 75% consists of stretch fabric and practically 25% of ordinary fabric, with the surface with the ordinary Tissue is arranged on the edge of the cap and. the stretch fabric has a warp from practically 125 to 135 threads of practically inelastic yarn per inch and a weft of 90 to 100 strands of stretch yarn per inch possesses, the stretch fabric also having an air 3 2 permeability from 0 to 12.2 m / m .min in practical draft-free condition under 12 mm WS pressure difference and air permeability with practically maximum draft 3 2 without permanent change in shape from 183 to 305 m / m. Min. at 12 mm WS has a pressure difference and where finally the direction of the primary stretch fabric dia * - 13 -00 9840 / 1.4 2 4 runs gonal to the cap radius. 29. Parachute according to claim 28, characterized in that the practical, inelastic yarn of the stretch fabric made of 30 denier high-strength nylon 66 and the stretch yarn of the stretch fabric made of 30 denier medium-strength counter-twisted (false twist) nylon. - 1 * - 009840/142 *