User talk:Averev

A given method and installation for flight in space was presented at the Would Space Congress-2002 [1]. This method uses the centrifugal force of a rotating circular cable that provides a means to launch a load into outer space and to keep the stations fixed in space at altitudes at up to 200 km. The proposed installation may be used as a propulsion system for space ships and/or probes. The suggested system may also be used as a high capacity energy accumulator.
The report and books [1-5] contains the theory of estimation and computation of suggested installations and four projects. Calculations include: a maximum speed given the tensile strength and specific density of a material, the maximum lift force of an installation, the specific lift force in planet’s gravitation field, the admissible (safe) local load, the angle and local deformation of material in different cases, the accessible maximum altitudes of space cabins, the speed than a space ship can obtain from the installation, power of the installation, passenger elevator, etc. The projects utilize fibers, whiskers, and nanotubes produced by industry or in scientific laboratories.

The installation includes (Fig. 1): a closed-loop cable made from light, strong material (such as artificial fibers, whiskers, filaments, nanotubes, composite material) and a main engine, which rotates the cable at a fast speed in a vertical plane. The centrifugal force makes the closed-loop cable a circle. The cable circle is supported by two pairs (or more) of guide cables, which connect at one end to the cable circle by a sliding connection and at the other end to the planet’s surface. The installation has a transport (delivery) system comprising the closed-loop load cables (chains), two end rollers at the top and bottom that can have medium rollers, a load engine and a load. The top end of the transport system is connected to the cable circle by a sliding connection; the lower end is connected to a load motor. The load is connected to the load cable by a sliding control connection.
The installation can have the additional cables to increase the stability of the main circle, and the transport system can have an additional cable in case the load cable is damaged.
The installation works in the following way. The main engine rotates the cable circle in the vertical plane at a sufficiently high speed so the centrifugal force becomes large enough to it lifts the cable and transport system. After this, the transport system lifts the space station into space.
The first modification of the installation is shown in Fig. 2. There are two main rollers 20, 21. These rollers change the direction of the cable by 90 degrees so that the cable travels along the diameter of the circle, thus creating the form of a semi-circle. It can also have two engines. The other parts are same.
fail: Circle Launcher and Space Keeper. Fig.1.pdf
Fig. 1. Circle launcher (space station keeper) and space transport system. Notations are: 1 – elastic cable circle, 2 – main engine, 3 – transport system, 4 – top roller, 5 – additional cable, 6 – the load (space station), 7 – mobile cabin, 8 – lower roller, 9 – engine of the transport system.

fail: Semi-Circle Launcher. Fig.2.pdf

Fig. 2. Semi-circle launcher (space station keeper) and transport system. Notation is the same with Fig. 1 with the additional 20 and 21 – rollers. The semi-circle is the same. The installation can be used for the launch of a payload to outer space (Fig. 3). The load is connected to the cable circle by a sliding bearing through a brake. The load is accelerated by the cable circle, lifted to a high altitude, and disconnected at the top of the circle (semi-circle).
The installation may also be used as transport system for delivery of people and payloads from one place to another through space (Fig. 4).
fail: Launcher the space Ship (probe. Fig.3.pdf

Fig. 3. Launching the space ship (probe) into space using cable elastic semi-circle. 27 – load, 28 – vacuum tube (option).
fail: Double semi-circle Launcher with opposed speed. Fig.4.pdf
Fig. 4. Double semi-circle with opposed speeds for delivery of load to another semi-circle end. 29 Roller.

This system works in the following way. The installation has two cable circles, which move in the opposite directions at the same speed. The space stations are connected to the cable circle through the sliding connection. They can move along the circle in any direction when they are connected to one of the cable circles through a friction clutch, transmission, gearbox, brake, and engine, and can use the transport system in Figs. 1 and 2 for climbing to or descending from the station. Because energy can be lost through friction in the connections, the energy transport system and drive rollers transfer energy to the cable circle from the planet surface. The cable circles are supported at a given position by the guide cables (see Project 2 in [3, Ch.3)]. No towers for supporting the circle cable are needed. (br/) The system can have only one cable (Figs. 1, 3).

Fig. 5. Cable circle around the Earth for 8–10 space objects. Notations are: 50 – double circle, 51 – drive stations, 52 – guide cable, 53 – energy transport system, 54 – space station.
fail: Double Cable Circle around the Earth. Fig. 5.pdf

The installation can have a system for changing the radius of the cable circle ([6], Fig. 3.9, p. 61). When an operator moves the tackle block, the length of the cable circle is changed and the radius of the circle is also changed.

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1. Detail manuscript “Circle Launcher and Space Keeper” was presented as Bolonkin’s paper IAC-02-IAA.1.3.03 at the Would Space Congress-2002, 10 19 October, Houston, TX, USA. (br/). 2. Centrifugal Keeper for Space Stations and Satellites, Journal British Interplanetary Society (JBIS), vol. 56, No 9/10, 2003, pp. 314-327. See in [1, pp.59-82]. (br/). 3. Bolonkin A.A., Non-Rocket Space Launch and Flight. Elsevier, 2006, 468 ps. Ch.3. ISBN-13: 978-0-080044-731-5, ISBN-10: 080044-731-7. (br/). 4. New Concepts, Ideas, and Innovations in Aerospace, Technology and Human Science, NOVA, 2008, 510 pgs. ISBN-13: 978-1-60021-787-6. ISBN-10: 1-60021-787-7. (br/).

5. Popular Review of new Concepts, Ideas, and Innovations in Space Launch and Flight (v2) ISBN 978-1- 365-98069-5 for paperback published by LULU in 2017. Ch.2. (br/).

6. Launch and Flight in Space without Rockets (v.2). LULU, 2011, p.55-72. Ch.3. ISBN 978-1-365-81382-5.

1. Launch and Flight in Space without Rockets. LULU, 2011, Ch.3, p.55-72. ISBN 978-1-365-81382-5. https://archive.org/download/IsbnBarcodeLaunchAndFlightv.261319.
. 2. “New Concepts, Ideas, Innovations in Aerospace, Technology and the Human Sciences”, NOVA, 2008, 510 pgs. ISBN-13: 978-1-60021-787-6. ISBN-10: 1-60021-787-7. http://viXra.org/abs/1309.0193.

3. Popular Review of new Concepts, Ideas and Innovations in Space Launch and Flight. USA, Lulu, 2017, 160 pg. ISBN 978-1-365-98069-5. Ch.2, p.10-13. http://viXra.org/abs/1705.0333.
Averev (talk) 21:49, 30 July 2019 (UTC)[reply]

Affected:

• File:Double Cable Circle around the Earth. Fig. 5.pdf

And also:

• File:Double semi-circle with opposed speeds. Fig. 4.pdf
• File:Launching the space ship. Fig .3.pdf
• File:Semi-circle Launcher and Space keeper. Fig.2.pdf
• File:Circle launcher and space keeper Fig1.pdf

Yours sincerely EugeneZelenko (talk) 14:28, 31 July 2019 (UTC)[reply]