RU2457160C1 - Shield for space vehicle protection against high-speed meteoroid impact action - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to space technology, namely to shields for space vehicle protection against high-speed meteoroid impact action. The shield contains cellular structure made of metal grid. The shield is made assembled of cells each one of which represents regular polygon and is made of two layers of metal grid squeezed along perimetre by flat-topped metal strips. In one of metal grid layers, pins are made bosses of which contact with other layer. Cells are cross-linked by metal wire.

EFFECT: saving in weight of protective shield.

8 cl, 2 dwg

Description

The screen for protecting a spacecraft from high-speed impact of meteoroids refers to the means of protecting spacecraft (SC) from meteoroids - space bodies intermediate in size between interplanetary dust and asteroids, including objects of artificial origin.

At present, various protective coatings and screens are used to protect the spacecraft from high-speed cosmic particles (meteoroids), upon collision with which these particles lose their energy.

It is known to use water ice as a protective coating for spacecraft from mechanical damage in orbit (RF patent 2265562 from 08.09.2003, B64G 1/56). This coating can be partially restored after a collision with micrometeorites, including small-scale fragments of space debris, and allows the spacecraft to be protected from these objects if they have too high speed and mass, but do not provide sufficient reliability and resistance to destruction, especially when exposed intense heat fluxes, including solar radiation.

A further development of this type of coating is a protective coating of the spacecraft from mechanical stresses, containing a layer of porous material filled with water ice or an ice-water mixture (RF application No. 2003133632 of 11/18/2003, publ. 04/27/2005, B64G 1/52). This coating is more resistant to destruction than the previous analogue, but since it is also made on the basis of ice, it is very fragile and prone to destruction. Restoring the place of destruction of the coating by pouring water and further freezing requires additional actions and time, which is not desirable in space flight conditions.

A device is known for maintaining the airtightness of the spacecraft’s shell in collisions with high-speed bodies (RF patent 2349515 dated November 30, 2006, B64G 1/56). It is made of one or more layers of elements located in the spacecraft’s protected volume, which begin to rotate when a meteorite or an external body passes through them. The elements have a cylindrical or spherical shape and each of the elements is placed in a rigid shell, which provides free rotation of the element. A lubricant layer is placed in the gap between the casing and the element, which solidifies upon contact with the substance of the indicated protected volume or as a result of a pressure drop. This device is more reliable and ensures the restoration of the spacecraft’s airtightness after a collision with small meteorites and space debris, but has too much mass and inertia when restoring the airtightness.

The closest analogue to the claimed screen for protecting the spacecraft from high-speed impact of meteoroids, selected as a prototype, is a device for protecting spacecraft and stations from high-speed impact of particles of the space environment (RF patent 2299839 from 08.12.2005, IPC B64G 1/56) . The device includes a protective screen made in the form of a cellular structure of a metal mesh, while the cell size does not exceed half the minimum characteristic size of meteor particles. Massive compact elements are fixed at the corners of the cells. The proposed screen design makes it possible to increase the spacecraft protection efficiency and reduce the mass of the protective structure by increasing the dispersion degree of destruction of the particles of the space environment and increasing the scattering angle of their fragments, however, it does not provide sufficiently effective protection of the spacecraft with increasing speed and mass of the particles of the space medium without increasing the mass of the screen.

The technical problem solved by the invention is to increase the efficiency of the screen while reducing its mass.

These tasks are ensured by the fact that in the known screen for protecting the spacecraft from high-speed impact of meteoroids containing a cellular structure of a metal mesh, the new thing is that the screen is made of prefabricated cells, each of which has the shape of a regular polygon and is made of two layers of metal nets compressed along the perimeter by n-shaped metal strips, moreover, at least in one of the layers of the metal mesh are made puklevki, the protuberances of which are in contact with rugim layer, the cells are stitched together with a metal wire.

In addition, the beetles are made on the inner layer of the screen and face their bulges towards the outer layer of the screen.

The gap between the layers of the screen is 10 mm.

Puklevki made in the form of a spherical segment, the radius of which is R≥H, where H is the distance between the layers of the screen, mm

Puklevki evenly placed over the cell area in increments of 30 cm.

The metal mesh is made of stainless steel wire with a diameter of 0.3 ... 0.34 mm with a mesh size of 0.5 ... 0.9 mm.

The cells are sewn with stainless steel wire with a diameter of 0.3 ... 0.34 mm.

In addition, a metal mesh is welded to U-shaped metal strips.

The implementation of the screen prefabricated from cells having the shape of a regular polygon and sewn together by a metal wire, makes it easy enough to adapt the shape and dimensions of the protective screen to the layout and design of a particular spacecraft.

The implementation of the screen cells from two layers of the metal mesh, crimped along the perimeter by p-shaped metal strips, and the presence in one of the layers of the metal mesh of puffles, the protuberances of which are in contact with the other layer, can increase the protective abilities of the screen and its strength while reducing the screen weight.

The implementation of the beetles on the inner layer of the screen and their convexity towards the outer layer of the screen allows us to provide the most optimal conditions for the interaction of both layers of the screen when counteracting the high-speed impact of meteoroids.

The gap between the layers of the screen, amounting to 10 mm, allows you to optimize the protective properties of the screen.

The implementation of the pupples in the form of a spherical segment, the radius of which is R≥H, where H is the distance between the layers of the screen, and the placement of the pupples uniformly over the cell area with a step of 30 cm provides an increase in the protective properties of the screen and simplifies the technology of its manufacture.

The implementation of the metal mesh of stainless steel wire with a diameter of 0.3 ... 0.34 mm with a mesh size of 0.5 ... 0.9 mm and stitching the cells with stainless steel wire with a diameter of 0.3 ... 0.34 mm can reduce the weight of the screen while maintaining its strength properties.

Welding the metal mesh to the u-shaped metal strips improves screen reliability.

The invention is illustrated by drawings, where:

figure 1 - General view of the screen;

figure 2 - General view of the cell.

The screen 1 for protecting the spacecraft from high-speed impact of meteoroids contains a structure assembled from cells 2 sewn together by stainless steel wire 3. The cells have the shape of a regular polygon and are made of two layers of a metal mesh 4, 5, crimped around the perimeter by u-shaped metal by strips 6. In one or both layers of the metal mesh, beams 7 are made, the protuberances of which are in contact with the other layer. Mostly the beetles are made on the inner layer 4 of the screen 1 and face their bulges towards the outer layer 5 of the screen 1. The recommended gap between the layers of the screen is 10 mm. Puklevki 7 is made in the form of a spherical segment, the radius of which is R≥H, where H is the distance between the layers of the screen, mm Puklevki are evenly spaced over the cell area with a step of 30 cm. The metal mesh 4, 5 is made of stainless steel wire with a diameter of 0.3 ... 0.34 mm with a mesh size of 0.5 ... 0.9 mm. The cells are sewn with stainless steel wire with a diameter of 0.3 ... 0.34 mm. The metal mesh is welded to the u-shaped metal strips 6.

When a meteoroid flying at high speed collides with the spacecraft, a shock action is created, initially perceived by the outer layer 5 of screen 1, and the elements of the grid 5 are introduced into the body of the meteoroid, leading to the destruction of the meteoroid and a change in the speed and direction of movement of its particles. Meteoroid particles penetrated through the outer layer 5 of screen 1 meet with the inner layer 4 of screen 1, where, due to the introduction of grid elements 4 into the body of meteoroid particles, they are further destroyed and their speed and direction of motion change to values safe for spacecraft.

At the same time, the presence of pupples providing contact between the screen layers with each other allows, on the one hand, to increase the strength properties of the lower layer of the screen, and on the other hand, to redistribute the loads between the outer and inner layers of the screen in a collision with a meteoroid flying at high speed, which increases screen properties while reducing its mass. The implementation of the screen by a prefabricated of cells having the shape of a regular polygon and sewn together by a metal wire allows us to simplify the manufacturing technology of the screen and, in general, increase the efficiency of spacecraft protection from high-speed impact by meteoroids.

Claims (8)

1. The screen for protecting the spacecraft from high-speed impact of meteoroids, containing a cellular structure of a metal mesh, characterized in that the screen is made of prefabricated cells, each of which has the shape of a regular polygon and made of two layers of metal mesh, crimped around the perimeter shaped metal strips, moreover, in at least one of the layers of the metal mesh, beams are made, the convexities of which are in contact with another layer, while the cells are sewn together by metal egg wire. 2. The screen according to claim 1, characterized in that the beetles are made on the inner layer of the screen and face their bulges towards the outer layer of the screen. 3. The screen according to claim 1, characterized in that the gap between the layer of the screen is 10 mm 4. The screen according to claim 1, characterized in that the beetles are made in the form of a spherical segment, the radius of which is R≥H, where H is the distance between the layers of the screen, mm 5. The screen according to claim 1, characterized in that the beetles are evenly distributed over the cell area in increments of 30 cm. 6. The screen according to claim 1, characterized in that the metal mesh is made of stainless steel wire with a diameter of 0.3-0.34 mm with a mesh size of 0.5-0.9 mm. 7. The screen according to claim 1, characterized in that the cells are sewn with stainless steel wire with a diameter of 0.3-0.34 mm 8. The screen according to claim 1, characterized in that the metal mesh is welded to p-shaped metal strips.

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