RU77844U1 - INSTALLATION FOR STARTING SPACE TECHNOLOGY OBJECTS - Google Patents

Abstract

The utility model relates to rocket and space technology and can be used to launch objects of space technology (OCT) for various purposes, for example satellites, probes, etc. The installation comprises a compression chamber in the form of a container consisting of a central working chamber filled with a light carrier gas, for example hydrogen, and two peripheral chambers separated from the central by sealed membranes and communicating with the atmosphere. A launch tube is connected to the compression chamber with an internal channel oriented by the exit towards the start and hermetically sealed by the upper hatch. Inside the channel there is a piston platform fixed in the lower and upper extreme positions. OCT is installed on the piston platform. Using a system made in the form of at least two pumps connected by pipelines to the channel, the over-piston space of the channel is evacuated. At the same time, overpressure is created in the compression chamber under the piston, the OCT platform is released and, under pressure, it moves upward through the evacuated pipe channel from the compression chamber to the extreme upper point where it stops, and the OCT, after acceleration, flies out through open team from the control panel hatch channel. The force from the pressure difference in the sub- and supra-piston space of the pipe channel provides the desired speed of departure of the OCT at a given height, for example, in the upper layers of the atmosphere where air is discharged. If necessary, the facility’s own engines are then switched on. As a result, the possibility of an economical and environmentally friendly launch of OCT is achieved, the arsenal of technical means that implements the method of launching OCT with its preliminary elevation to the place of launch into operational orbit is expanding.

Description

The utility model relates to astronautics, more precisely rocket and space technology and can be used to launch space technology objects (OCT) using gas pressure.

A device is known for launching space technology objects (OCT), for example, for launching a satellite into orbit (RU 2117610 C1, 1998), comprising an accelerator complex and a launch tube, the inner channel of which is separated from the atmosphere by a film covering its upper end and the lower end the pipes are connected to the accelerator complex, which gives the satellite the necessary speed. The purpose of the launch tube in this device is to protect the satellite launched by the launch vehicle from air resistance. However, the need to use a launch vehicle throughout the launch does not significantly reduce the consumption of rocket fuel and, consequently, the cost of launch, as well as reduce environmental pollution from fuel combustion products.

These disadvantages are eliminated in the well-known installations for launching OCT, in which the launch object is first moved to a certain height using simple, non-polluting equipment, for example, lifts. Of these, the closest analogue (prototype) of the proposed utility model by the number of matching essential features is a device for supplying a launch object: a projectile, rocket or other space technology to its destination (RU 2172462 C2, 2001), containing a compression chamber connected to the compressor, a launch tube having an internal channel oriented towards the launch side and at the input communicating with the compression chamber, and intended to contact the launch object, a platform located above the compression chamber in the internal channel with

the ability to move along it under the action of pressure from this chamber, as well as means for fixing the platform in its original position and stopping it at the end of the movement before the exit of the internal channel. The compression chamber in the prototype is part of the volume of the internal channel of the pipe (barrel muzzle) under the platform and is connected by pipelines to a separately spaced compressor. The platform moves along the guides inside the barrel and is fixed in the initial position by special clamps, and in the final position by stopping in the shoulder in the channel wall. After installing the launch object on the platform in the compression chamber through the pipeline from the compressor, air is pumped to the maximum pressure and under the influence of this pressure the platform moves forward, presses on the object and throws it out of the pipe, providing a certain flight range. If necessary, further promotion of the object is carried out by its own engine.

The functionality of the prototype device is limited, its use is effective in launching shells or missiles at relatively low altitudes and is not suitable for launching OCT at significant heights due to the limited capabilities of the compression chamber in it, due to both its parameters and structural dependence on the pipe channel, as well as the output technical data of the compressor used.

The task and technical solution of the utility model is to expand the arsenal of technical means that implement the method of launching OCT with its preliminary launch to the launch position in outer space, in order to reduce the energy costs of launching, the cost of creating rockets, as well as the consumption of rocket fuel.

The essence of the utility model lies in the fact that the installation for launching objects of space technology containing a compression chamber, a launch tube having an internal channel, oriented exit to the launch side and

at the entrance, it communicates with the compression chamber, and is intended for contact with the object, a platform placed above the compression chamber in the internal channel with the possibility of moving along it under pressure from this chamber, as well as means for fixing the platform in its original position and stopping it at the end of the movement before the output of the internal channel, in contrast to the prototype, is equipped with a system for evacuating the internal channel of the launch pipe, made in the form of at least two pumps connected by pipelines to the channel above the boards the form, which in this case is made in the form of a piston of the internal channel having a sealed opening cover at the outlet, the compression chamber in it is made in the form of a container consisting of a central closed working chamber filled with light carrier gas and two peripheral chambers separated from the central by sealed membranes while the peripheral chambers are configured to communicate with the atmosphere, are provided with airtight covers and are connected to said pumps.

In particular cases of implementation, the differences are that the working chamber is filled with hydrogen or helium.

The implementation of the inner channel is evacuated and the compression chamber is simple in design in the form of a container, the central part of which is located under the platform, is filled with light carrier gas, and the peripheral ones create the necessary working pressure, which ensures efficient OCT operation with low economic costs. The implementation of the platform in the form of a piston of the internal channel simplifies the design (there is no need for guides) and allows more efficient use of pressure.

In the presented drawings: in Fig.1 is a General view of the installation in section (example), in the initial position; figure 2 is the same at the final moment of operation; figure 3 is a General view of the installation in plan (example).

The installation comprises a compression chamber 1 made in the form of a container consisting of a central closed working chamber 2 filled with a light carrier gas, such as hydrogen or helium, and two peripheral chambers 3 filled with atmospheric air, which are separated from the chamber 2 by sealed membranes 4.

The launch tube 5 contains an inner channel 6, the lower end of which communicates with the compression chamber 1. Channel 6 at the upper end has an exit hatch 7, hermetically closed by an opening lid 8.

The installation contains a vacuum system of the internal channel 6, consisting of m.m. of two pumps 9 (their number depends on the evacuation volume of the nadporshny space of the channel) connected by pipelines 10 with chambers 3 on the one hand, and channel 6 of the launch pipe 5 on the other hand. The chambers 3 have hatches 11 for connecting to the atmosphere with hermetically sealed covers 12. Inside the channel 6 there is a piston platform 13, which can be fixed in the lowermost position with stops 14 and in the highest upper position with stops 15, designed to install OCT 16 through the loading window in pipe (not shown conditionally in the drawings).

In the initial position of the installation on the platform of the piston 13 is installed OKT 16 through the boot window, which then closes tightly. The piston platform 13 is locked in the lowermost position by the stops 14. The covers 12 of the chambers 3 are open to provide atmospheric pressure in these chambers and the same pressure acts on each membrane 4 from the side of the central chamber 2 and from the side of the peripheral chamber 3. The cover 8 of the channel 6 is in the closed position.

The launch is carried out in the following order.

The covers 12 of the chambers 3 are closed, with the help of pumps 9 a vacuum is created in the supra-piston region of the inner channel 6, and in the peripheral chambers 3 an excess air pressure is created, under the action of which the membranes 4

they bend into the inside of the chamber 2. With the achievement of the necessary overpressure in the chamber 2, the stops 14 are removed, the platform-piston 13 is unlocked and begins to move up the channel 6 under the action of excess pressure from the side of the compression chamber 2.

At some point in time, the piston platform 13 is in the highest position of the inner channel 6 of the pipe 5, where it is braked and fixed by the stops 15. At the same time, the cover 8 automatically opens and the OCT 16 flies out of the launch tube. The force from the pressure difference in the sub- and supra-piston space of the pipe channel 6 provides the desired departure speed of the OCT 16 at a given height.

The tight cover 8 closes, the excess pressure in the peripheral chamber 3 is vented to the atmosphere through the open covers 12, the pumps 9 pump air into the supra-piston space to the pressure necessary so that the forces from the pressure difference in the sub- and supra-piston spaces of the pipe equalize and the piston platform 13 lowered to its lowest position under the influence of its own weight, where it is fixed by the stops 14. The unit is returned to its original position and is again ready for operation.

A specific example of the implementation of the technical solution is illustrated by the following calculations.

Let P denote the pressure acting on the platform piston with the space technology object placed on it, then

P = P _atm -p * g * h, where

P _atm is atmospheric pressure;

p is the density of hydrogen;

h is the height to which the platform piston rises in the pipe;

h = (P _atm -P) / p * g

at P = 0

h _max = P _atm / p * g

It is known that at an altitude of 20 km the air density is 15 times lower than its value at sea level, therefore, at altitudes of more than 20 km, air resistance can be neglected.

When the diameter of the inner channel 6 of the pipe 5 in a specific example is equal to D _pipe = 1 m, the area in the cross section of the pipe is: S = (P * D ^ 2 _pipes ) /4=3.14/4=0.785 m ^ 2, then the volume of the pipe

V _trip = S * h _trip = 0.785 * 20 * 10 ^ 3 = 15.7 * 10 ^ 3 m. ^ 3

The capacity volume is equal to V _capacity = 16.8 * 10 ^ 3m ^ 3, with D _capacity = 16 m.,

and the height h of the _tank = 84 m. (the volume of hydrogen in the tank should be slightly larger than the volume of the pipe).

The force from the action of the pressure difference in this case is equal to:

F = P * S _pipe = (10 ^ 5) * 0.785 = 78.5 kN,

which, with the mass of the space technology object m = 100 kg located on the piston platform, provides a departure speed of V = 2000 m / s from the upper part of the pipe channel 5, at an altitude of 20 km.

After the departure of OCT 16 from the internal channel of the launch tube of the installation on it, if necessary, its own engines are switched on, which bring it to a higher predetermined orbit.

Claims (3)

1. Installation for launching objects of space technology, containing a compression chamber, a launch tube having an internal channel, oriented by the exit towards the launch and at the entrance in communication with the compression chamber, and designed to contact the object, a platform located above the compression chamber in the inner channel with the possibility moving along it under the action of pressure from this chamber, as well as means for fixing the platform in the initial position and stopping it at the end of the movement before the exit of the internal channel, characterized in that it equipped with a system for evacuating the inner channel of the launch pipe in the form of at least two pumps connected by pipelines to the channel above the platform, which is in this case made in the form of a piston of the internal channel having a sealed opening lid at the outlet, the compression chamber in it is made in the form of a container consisting of a central closed working chamber filled with light carrier gas, and two peripheral chambers separated from the central by sealed membranes, while the peripheral chambers are configured to communications with the atmosphere, equipped with sealed covers and connected to the mentioned pumps. 2. Installation according to claim 1, characterized in that the working chamber is filled with hydrogen. 3. Installation according to claim 1, characterized in that the working chamber is filled with helium.