RU146496U1 - VANE SHOULDER - Google Patents

Abstract

1. A blade parachute, including slings, a dome with a central part and side blades interconnected by flexible ties, and fastening elements of flexible ties, characterized in that the elements are placed on the outside of the central part of the dome. The blade parachute according to claim 1, characterized in that the elements are fixed in one common place. 3. The paddle parachute according to claim 1, characterized in that the place of attachment of the fastening elements of the flexible connections is located in the middle of the central part of the dome. The paddle parachute according to claim 1, characterized in that the fastening elements of the flexible connections are located crosswise. 5. The paddle parachute according to claim 1, characterized in that the fastening elements of the flexible links are oriented along the angles of the blades. 6. The paddle parachute according to claim 1, characterized in that the fastening elements of the flexible connections are hollow. The paddle parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made of variable cross section. The paddle parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made tapering. The paddle parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made of elastic materials. 11. The blade parachute according to claim 1, characterized in that a polymer coating is applied to the inner surface of the fastening elements of the flexible ties. The paddle parachute according to claim 10, characterized in that the coating is applied intermittently. 12. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made of at least two parts interconnected. Vane parachute according to claim 1, characterized in that the fastening elements are flexible

Description

The invention relates to a parachute technique, namely, to the construction of a parachute having a blade-shaped dome.

The utility model can be used as a means of rescue, or braking of cargo and payload in aeronautics, aviation, astronautics, shipbuilding, automotive, sports, and in the entertainment industry.

The blade parachute is essentially a cruciform parachute, the dome of which consists of a central part, which is a square and at least four blades attached to the central part along its sides, as well as slings attached along the outer edges of the blades forming the input dome hole. (see RF Patent No. 2267448 according to class B64D 17/02, 2001)

The process of filling the canopy of the parachute is the most important stage in the process of its functioning. It is known that it proceeds quickly enough and is accompanied by a continuous change in the shape of the canopy of the parachute and is characterized by a significant increase in loads, to reduce which various methods are used to slow down the process of opening the parachute.

As the deceleration devices can be individual elements of the parachute, devices mounted on the dome or slings, or additional elements of the parachute block, for example, additional covers.

Known blade parachute containing a dome with slings, and the lower edges of the blades connected by flexible elements, tightened by a destructible connection. (AS USSR No. 42615, class B64B 17/02, 1973)

The disadvantages of the known design are:

- possible adhesion of the blades in the process of pulling the parachute, which leads to instability of the filling and opening process ;;

- with small corrugation parameters, the strongly drawn-down lower edge forms folds and blocks the inlet of the dome, which affects the filling of the dome.

- the difficulty of laying the parachute, since the individual blades protrude in different directions, which leads to turning the individual blades inside out.

The closest in technical essence to the proposed technical solution is a winged parachute, including slings, a dome with a central part and side blades interconnected by flexible links, and elements for securing the slings on the dome (see AS No. 525287 according to class B64D 17 / 02, 1995)

The disadvantages of the known design are:

- the duration and instability of the parachute;

- the complexity and the possibility of making mistakes during installation;

- increase in the number of elements necessary for the functioning of the parachute.

These shortcomings lead to a decrease in the reliability of parachute deployment and increase the number of hazards that can lead to the realization of the risks of parachute failure.

The technical result solved by the proposed utility model is the creation of a parachute design that allows a controlled process for the introduction, pulling and filling of the parachute.

The technical result in the proposed utility model is achieved by creating a blade parachute, including slings, a dome with a central part and side blades interconnected by flexible ties, and elements for fastening flexible ties, in which according to the utility model, fastening elements of flexible ties are placed on the outside of the central parts of the dome.

The implementation of the elements of fastening flexible connections hollow allows for the oriented placement of flexible connections inside the elements.

The implementation of the fastening elements of flexible connections of variable cross-section provides different efforts at the exit of flexible connections from the elements and eliminates their premature exit when pulling the parachute and the dynamic loads that accompany this process.

The implementation of the fastening elements of flexible ties tapering from the place of their fastening allows for unambiguous fixation and braking force when the flexible ties exit the fastening elements, excluding burning on the surface of the fastening elements with parachute design options with exceptionally quick opening.

The implementation of the fastening elements of flexible ties tubular eliminates longitudinal seams that can affect the flexible elements when they are placed inside the tubular elements and in the process of their exit.

The implementation of the fastening elements of flexible bonds, consisting of at least two parts connected together ensures ease of manufacture and allows the use of materials with different friction characteristics in contact with interacting materials.

Currently, materials are being produced, for example, kapron avisent, fabrics with polyvinyl chloride coating (PVC fabrics), kapron fabrics with different friction and slip resistance. Sliding resistance is determined by the average traction force in accordance with GOST R ISO 5905-95.

In the process of functioning of various purpose parachute systems, the requirements for the time of pulling and filling may be different. In one case, the process should proceed as quickly as possible, in the other - as slowly as possible. Using materials with different properties in the fastening elements, for example, elongation can be varied by this process.

For this, in the proposed utility model, each part of the element is made of a material with different properties.

In the proposed paddle parachute, the fastening elements of flexible ties are made of elastic materials, for example, fabrics, films, rubber, etc.

One of the main advantages of a parachute is its compactness, i.e. ability to accommodate in relatively small volumes. This is facilitated by the use of flexible materials and styling procedures to ensure an orderly introduction of the parachute.

The presence of any element of the parachute made of hard materials is a stress concentrator, complicates the installation process, increases the risks of damage to the canopy and the parachute at different stages of the life cycle: installation, transportation, storage and operation.

The blade parachute is also characterized by the fact that a coating is applied to the inner surface of the fastening elements of the flexible ties. The processes of the output of elements of parachute systems from cells, gazyrs, cavities, etc. due to the significant rates of their progress, they are accompanied by the use of materials from synthetic fibers “burning” of the latter.

As a result, damage is obtained on the surfaces of the materials of the moving parts, leading to a decrease in their strength. With repeated use of parachutes, the use of conventional fabrics will require the replacement of flexible ties and fastening elements after each use of the parachute.

The application of fireproof coatings on the inner surface of the fastening elements of flexible ties allows you to reduce the impact of the processes of "burning" of materials and to ensure repeated use of the parachute without repair.

Coatings can be performed, for example, in the form of impregnations that are applied to the fabric during its finishing, either in the form of films fixed to the fabric, or in the form of aerosol substances applied to the surface of the fastening elements of the flexible bonds of the coating before placing flexible bonds in them.

The supply of the ends of the fastening elements of the flexible connections with cuffs is necessary to exclude the destruction of the fastening elements at the ends in the process of the output of flexible ties.

The winged parachute is also characterized in that the cuffs are made on the outside of the fastening element of the flexible ties in order to exclude additional effects on the flexible ties, which can lead to loss of strength.

The fastening of the fastening elements of flexible connections in one place provides the convenience of laying and functioning, even in the presence of industrial deviations.

The location of the fastening elements of the fastening elements of the flexible connections in the middle of the central part of the dome is necessary to perform the fastening elements of the same length and the same path of movement of the flexible connections placed inside the fastening elements, when they exit.

Each fastening elements of flexible connections has a slot in the place of their fastening.

The slot is necessary to ensure an oriented arrangement of double-folded flexible connections inside the fastening elements, to eliminate their confusion and ease of installation.

The location of the fastening elements of the flexible connections crosswise in the corners of the connection of the blades provides an oriented arrangement of the fastening elements and flexible connections placed in them, in the direction of their exit, provides the same length and the same path of movement of the flexible connections.

At the stage of putting into operation, the central part of the blade parachute is perpendicular to the incoming flow, representing in the plane an ordinary square. This allows you to reduce the drag coefficient without the use of additional devices tightening the inlet of the parachute.

The proposed design of the blade parachute allows you to form a continuous edge around the perimeter of the Central part of the dome due to the location and fixation of the blades on its outer surface.

It also facilitates the laying process and increases the reliability of operation by eliminating the possibility of turning the blades out.

In the proposed utility model, it is not required to use fabrics with zero or near air permeability in the central part of the dome due to the location on it in several layers with overlapping folded side blades. Due to this, the air permeability of the canopy of the parachute is reduced at the initial stage and the filling speed increases.

When conducting patent research, no solutions were found identical to the declared one, and, therefore, the claimed utility model meets the criterion of "novelty."

We believe that the information presented in the application materials is sufficient for the practical implementation of the utility model.

The essence of the proposed utility model is illustrated by the following description and drawings, where

In FIG. 1 shows a general plan view of a winged parachute. In FIG. 2 shows a view AA of FIG. 1 in FIG. 3 shows a view BB of FIG. one

In FIG. 4 shows a top view of the proposed utility model, where two of the four blades are conventionally not shown,

The blade parachute includes a dome with a central part 1 and side blades 2, slings 3, and the side blades 2 are interconnected by flexible ties 4, and the elements for their fastening 5 are placed and fixed on the outside of the central part 1 of the dome in one place 6, having slot 7.

Elements for fixing 5 flexible ties 4 can be made of variable cross-section or of several parts, for example, 8, 9, 10. Each part can be made of materials with the same properties, as well as materials with different properties, different friction and sliding resistance .

The fastening elements of the flexible connections at their ends have cuffs 11 to prevent the destruction of the fastening elements at the ends in the process of exiting flexible connections.

Laying the proposed paddle parachute is as follows:

Each side blade 2 is folded in half and the diametrically located blades are placed alternately on the outer surface of the central part 1 of the dome.

In this case, a second pair of blades is located above the first pair of blades.

After that, each flexible connection 4 is folded in half, and alternately placed in the fastening elements 5, fixed at one point 6 on the central part and oriented in a certain way along the angles of attachment of the side blades to the central part.

To ensure an oriented arrangement of flexible connections 4 in the elements for their fastening, use the slots 7 located on the elements for fixing in the area of their attachment to the Central part. Technological devices, for example, are passed through the slots 7 from the attachment side of the elements at point 6, for example, with the help of which they provide preliminary fastening of the flexible ties folded in half 4 and their oriented placement in the fastening elements 5.

After that, technological devices through the slots 7 are removed without violating the oriented location of the flexible connections 4.

Depending on the problem being solved and the conditions for the functioning of the winged parachute, the elements for securing flexible connections can have various designs that provide not only fixation of flexible connections when equipping a winged parachute, but also different exit speeds of flexible connections from them when filling the parachute.

With the introduction of a blade parachute into the stream, aerodynamic loads act only on the central part of the parachute. The location on the outer surface of the side blades 2 prevents them from sticking together, diving or twisting the blade parachute.

After pulling, the blade parachute is gradually filled, during which the lateral blades move relative to the central part, while at the same time pulling the flexible links 4 from the elements 5. After the flexible links 4 are completely removed, the blade parachute takes on a classic shape, which allows braking and lowering loads at a given speed.

Claims (14)

1. Vane parachute, including slings, a dome with a central part and side blades interconnected by flexible connections, and fastening elements of flexible connections, characterized in that the elements are placed on the outside of the central part of the dome. 2. Vane parachute according to claim 1, characterized in that the elements are fixed in one common place. 3. The blade parachute according to claim 1, characterized in that the place of attachment of the fastening elements of the flexible connections is located in the middle of the central part of the dome. 4. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are located crosswise. 5. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are oriented at the angles of the blades. 6. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are hollow. 7. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made of variable cross-section. 8. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made tapering. 9. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made of elastic materials. 10. The blade parachute according to claim 1, characterized in that a polymer coating is applied to the inner surface of the fastening elements of the flexible ties. 11. Vane parachute according to claim 10, characterized in that the coating is applied intermittently. 12. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are made of at least two parts interconnected. 13. The blade parachute according to claim 1, characterized in that the fastening elements of the flexible connections are provided with cuffs. 14. The blade parachute according to claim 1, characterized in that each element has a slot in the place of its fastening.

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