DE717633C - Parachute, which consists of several deformable parts that complement each other to the usual parachute surface - Google Patents

Description

Parachute, made up of several deformable ones, becoming the usual parachute surface complementary parts there is the demand for arbitrary influence on the rate of descent The versatile use of the parachute makes it more urgent than ever. On the one hand is used to land safely for the parachute user, d. H. after his jump, -A high rate of descent is desired, so as to be drifted as little as possible by the wind on the other hand, the rate of descent is allowed at the moment of landing Do not exceed the maximum limit, since the parachute user is without injury Should reach the bottom. These two demands can only be met by one as possible extensive regulation of the rate of descent of the parachute while floating downwards unite: All parachute designs known so far are based on adjustability part of the glider surface by hand-pulled control lines or by the Shift rank .des. Body weight, in turn, through hand strength. The achievable here Increase in the speed of fall is unlikely to have any appreciable ratio reach the normal rate of descent of the parachute concerned.

The invention has the purpose of this ratio of the two Sinkgeschwindigk The ability to change the size of the effective screen surface can be increased especially when intercepting the required energy instead of muscle power from the dynamic pressure is to be raised. This energy is z. B. when intercepting one with double the rate of descent downward floating umbrella. a multiple of the maximum by simply shifting one's body Reachable.

For example, to intercept from 14 to 7 m / sec. a workload of 735 mkg is required for a load of roo kg. That would mean a shift of the assumed load of 1ookg by 7.35 m, which could never be achieved structurally.

In what way the dynamic pressure through the parachute in the subject of the invention can be used to slow down the rapid fall, goes from the following Description.

The parachute (Fig. I) consists of a two-part umbrella surface, namely the umbrella ring i and the cap 2, which are connected to the umbrella bag 3 by a three-part suspension line system q., 5 and 6. The line groups .l and 5 run out here in free rope ends 7 and 12, while the central line 6 forks up into the conical end group 9. In the phase shown in Fig. I, the parachute sinks with the slower fall speed. If it is now to be accelerated, it is adjusted to the phase shown in Fig. 2. This consists in that the umbrella ring i maintains its position relative to the umbrella bag 3, as does the middle part of the cap 2, while the lower edge iij of the same is released and folds up as a result of the dynamic pressure. For this purpose, the rope end 7 and thus the suspension lines 4. of the canopy are loosened by a tight belnessen.e rope length, while the suspension lines 5 of the umbrella ring and the middle line 6 continue to bear the load of the parachutist. In order to promote the mutual movement between the umbrella ring i and the cap 2, the lines 4 are guided through ring eyelets 8 attached to the umbrella ring. The bifurcation of the line 6 into the conical end group 9 - the center piece of the cap - prevents the canopy from folding up, which later enables the umbrella to be intercepted as shown in Fig. 3. The ring-shaped gap created by the process described allows the air trapped under the screen to escape directly to the top of the screen, which naturally reduces the carrying capacity of the screen or increases the rate of descent. The interception of the parachute to return it to the state of the lowest sinking speed takes place in three phases.

First, the middle suspension line 6 is relieved by slackening the same length of the rope as mentioned above, whereby the canopy 2 turns inside out to its normal length, so that the edge i I of the same comes to lie down again and thereby the canopy the phase in Fig .3 occupies. So - then the rope ends ia and thus the 1-ef *, en 5 of the umbrella ring are loosened by the same length, whereby the latter collapses and the umbrella looks like the one in Fig. 4 phase shown.

The transition to the last phase then takes place automatically by that the loose umbrella ring is pushed up by the dynamic pressure on the cap 2 until finally the gap io has closed. Then the screen opens again to the full screen area and thus assumes the initial phase (Fig. i), with the The only difference is that the rope ends 7, 12 and 6 all do .ein the same piece have become longer compared to the initial phase.

The change in the rate of descent during the individual phases the opening shape of the screen surface is illustrated by Fig. 5, which is a Plots the rate of descent as a function of time.

Claims (1)

I'A-rEINTA1sPRuc11: parachute, the deformable from a plurality of itself consists of the usual screen surface complementary parts, which are adjustable to one another to form an annular gap or cancellation between the adjacent screen surfaces, characterized denotes Ge, that preferably the-.an with a parachute canopy (2) provided with a crown opening, two multi-link groups of lines (4 and 9) are articulated, one of which (9) on the inside of the canopy (2) at a distance from its edge, while the other (.1) on the edge ( ii) attacks the canopy (2), but both converge separately to form individual suspension lines (6 and 7), with the suspension lines (q.) attached to the cap edge (ii) being guided through eyelets (8) attached to the lower ring-like parachute part (i) are, and that both the third suspension line group (5) which grips at the lower edge of the ring canopy surface (i) and which also unites to form a single suspension line (12), as well as the other two groups of suspension lines (.4, 7 or 9, 6) are releasably attached to the parachute riser in such a way that they can all be relieved by the same amount one after the other in a predetermined order.