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Theoretical Models of Sound Speed Increase Effects in Gas Duct with Corrugated Wall Authors: Konokh V. Content 2018 (2) Downloads: 34 Abstract views: 1227 Dynamics of article downloads Dynamics of abstract views Downloads geography Country City Downloads USA Boardman; Ashburn; Ashburn; Matawan; Plano; Columbus; Phoenix; Phoenix; Phoenix; Los Angeles; Monroe; Ashburn; Seattle; Ashburn; Ashburn; Seattle; Tappahannock; San Mateo; Des Moines; Boardman; Boardman; Ashburn 22 Singapore Singapore; Singapore; Singapore; Singapore 4 Ukraine Dnipro; Dnipro 2 Unknown Brisbane 1 Finland Helsinki 1 Canada Monreale 1 Germany Falkenstein 1 Romania Voluntari 1 Netherlands Amsterdam 1 Downloads, views for all articles Articles, downloads, views by all authors Articles for all companies Geography of downloads articles Konokh V. Theoretical Models of Sound Speed Increase Effects in Gas Duct with Corrugated Wall Автори: Konokh V.
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7. Theoretical Models of Sound Speed Increase Effects in Gas Duct with Corrugated Wall

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine1; National Technical University “Kharkiv Polytechnic Institute”, Kharkiv, Ukraine2

Page: Kosm. teh. Raket. vooruž. 2018 (2); 57-67

DOI: https://doi.org/10.33136/stma2018.02.057

Language: Russian

Annotation: During experimental investigation of the dynamic characteristics of a pneumatic test bench for testing liquid rocket engine high-flowrate automatic units, the effect was detected of 20-35% sound speed increase in the gas flow moving along the channel with corrugated wall (metal hose) which is a part of test bench drain system. The article presents the results of experiments and the task of theoretical justification of the effect is solved. It is indicated that its causes may be two mutually complementary factors – a decrease of gas compressibility at eddy motion and oscillations of metal hose wall. The physical model is considered that describes variation of gas elasticity and density in the conditions of high flow vorticity. It is supposed that in the near-wall layer of the channel, toroidal vortexes (vortex rings) are formed, which move into turbulent core of the flow where their size decreases and the velocity of rotation around the ring axis of torus increases. The spiral shape of the corrugation ensures also axial rotation, which increases vortexes stability. The intensive rotation around the ring axis creates considerable centrifugal forces; as a result, the dependence of pressure on gas density and the sound speed increase. The mathematical model has been developed that describes coupled longitudinal-lateral oscillations of gas and channel’s corrugated shell. It is indicated that in the investigated system, two mutually influencing wave types are present – longitudinal, which mainly transfer gas pressure pulses along the channel and lateral ones, which transfer the shell radial deformation pulses. As a result of modeling, it has been ascertained that because of the lateral oscillations of the wall, the propagation rate of gas pressure longitudinal waves (having the same wave length as in the experiments at test bench) turns out to be higher than adiabatic sound speed.

Key words: rocket engine automatic units, pneumatic test bench, metal hose, corrugated shell, toroidal vortex, longitudinal-lateral oscillations

Bibliography:
1. Shevchenko S. A. Experimental Investigation of Dynamic Characteristics of Gas Pressure Regulator in Multiple Ignition LRE Starting System. Problems of Designing and Manufacturing Flying Vehicle Structures: Collection of scientific works. 2015. Issue 4 (84). P. 49-68.
2. Shevchenko S. A., Valivakhin S. A. Results of Mathematical Modeling of Transient Processes in Gas Pressure Regulator. NTU “KhPI” News. 2014. No. 39 (1082). P. 198-206.
3. Shevchenko S. A., Valivakhin S. A. Mathematical Model of Gas Pressure Regulator. NTU “KhPI” News. 2014. No. 38 (1061). P. 195-209.
4. Shevchenko S. A., Konokh V. I., Makoter A. P. Gas Dynamic Resistance and Sound Speed in Channel with Corrugated Wall. NTU “KhPI” News. 2016. No. 20 (1192). P. 94-101.
5. Flexible Metal Hoses. Catalogue. Ufimsky Aggregate Company “Hydraulics”, 2001.
6. Loytsyansky L.G. Liquid and Gas Mechanics. М., 1978. 736 p.
7. Prisnyakov V. F. et al. Determination of Gas Parameters at Vessel Emptying Taking into Account Compressibility and Manifold Resistance. Problems of High-Temperature Engineering: Collection of scientific works. 1981. P. 86-94.
8. Kirillin V. A., Sychyov V. V., Sheydlin A. E. Technical Thermodynamics. М., 2008. 486 p.
9. Grekhov L. V., Ivashchenko N. A., Markov V. A. Propellant Equipment and Control Systems of Diesels. М., 2004. 344 p.
10. Sychyov V. V., Vasserman A. A., Kozlov A. D. et al. Thermodynamic Properties of Air. М., 1978. 276 p.
11. Shariff K., Leonard A. Vortex rings. Annu. Rev. Fluid Mech. 1992. Vol. 24. P. 235-279. https://doi.org/10.1146/annurev.fl.24.010192.001315
12. Saffman F. Vortex Dynamics. М., 2000. 376 p.
13. Akhmetov D. G. Formation and Basic Parameters of Vortex Rings. Applied Mechanics and Theoretical Physics. 2001. Vol. 42, No 5. P. 70–83.
14. Shevchenko S. A., Grigor’yev A. L., Stepanov M. S. Refinement of Invariant Method for Calculation of Gas Dynamic Parameters in Rocket Engine Starting Pneumatic System Pipelines. NTU “KhPI” News. 2015. No. 6 (1115). P. 156-181.
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7.2.2018 Theoretical Models of Sound Speed Increase Effects in Gas Duct with Corrugated Wall
7.2.2018 Theoretical Models of Sound Speed Increase Effects in Gas Duct with Corrugated Wall
7.2.2018 Theoretical Models of Sound Speed Increase Effects in Gas Duct with Corrugated Wall

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5.2.2018 Electromagnetic Valves Developed by Yuzhnoye SDO Liquid Rocket Engines Design Office https://journal.yuzhnoye.com/content_2018_2-en/annot_5_2_2018-en/ Thu, 07 Sep 2023 11:01:49 +0000 https://journal.yuzhnoye.com/?page_id=30749
Electromagnetic Valves Developed by Yuzhnoye SDO Liquid Rocket Engines Design Office Authors: Konokh V. Content 2018 (2) Downloads: 35 Abstract views: 1360 Dynamics of article downloads Dynamics of abstract views Downloads geography Country City Downloads USA Matawan;; Boydton; Plano; Dublin; Dublin; Phoenix; Phoenix; Phoenix; Monroe; Ashburn; Ashburn; Boardman; Seattle; Portland; Portland; Des Moines; Boardman; Boardman; Ashburn 20 Singapore Singapore; Singapore; Singapore; Singapore; Singapore 5 Unknown ; Hong Kong 2 Ukraine Kyiv; Dnipro 2 Finland Helsinki 1 Iran 1 Canada Monreale 1 Germany Falkenstein 1 Romania Voluntari 1 Netherlands Amsterdam 1 Downloads, views for all articles Articles, downloads, views by all authors Articles for all companies Geography of downloads articles Konokh V. Electromagnetic Valves Developed by Yuzhnoye SDO Liquid Rocket Engines Design Office Автори: Konokh V.
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5. Electromagnetic Valves Developed by Yuzhnoye SDO Liquid Rocket Engines Design Office

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2018 (2); 34-48

DOI: https://doi.org/10.33136/stma2018.02.034

Language: Russian

Annotation: In the pneumohydraulic systems of liquid rocket engines and propulsion systems, electromagnetic valves that allow making the pneumohydraulic systems more simple and ensuring multiple ignition of liquid rocket engines have found wide application. The Yuzhnoye-developed electromagnetic valves are designed according to two schemes – of direct and indirect action. In the direct-action electromagnetic valves, the shutting-off device opens (closes) the throat with the force developed by electric magnet. They have gained acceptance in the pneumohydraulic systems with the working medium pressure of ~8.5 MPa, they are of simple design and have high operating speed (0.001…0.05 s). In the electromagnetic valves with amplification, the electromagnet armature is connected with control valve and the main shutting-off device moves due to the force from working medium pressure drop on it. They are used in the operating pressure range of 0.5…56 MPa, at that, the action time is 0.025…0.15 s. For the European Vega launch vehicle fourth stage main engine assembly that has pressure propellant feeding system, the electrohydraulic valve with amplification and drainage was developed. The dependence of this electrohydraulic valve high speed from the line’s output length is decreased to the maximum due to the installation of Venturi nozzle at the output connecting branch. This electrohydraulic valve is operable at the pressure below 8 MPa, the action time is 0.08…0.12 s. The present-day spacecraft gas-jet orientation and stabilization systems use as propulsion devices the electromagnetic valves with nozzles whose thrust is, as a rule, not more than 30 N and the working medium pressure is up to 24 MPa. Yuzhnoye State Design Office developed for 15B36 gas-jet system the electropneumatic valve with amplification and nozzle, which is operable at the pressure below 45 MPa, ensures the action frequency of up to 10 Hz and is capable of creating the thrust of 100 N on gaseous argon. To solve the task of decreasing the dependence of operability and high speed of electromagnetic valves with drainage and amplification on geometry of lines in which a valve is installed, the electropneumatic valve was developed that has spool elements ensuring reliable and quick action with long input lines of 0.004 m diameter. Its mass is 2…2.5 times lower than the mass of analogs. Recently, Yuzhnoye State Design Office develops the apogee RD840 LRE with 400 N thrust, for the conditions of which the direct-action electrohydraulic valve was developed and tested with the following characteristics: pressure – up to 2.15 MPa, consumed power in operation mode – less than 7.1 W, action time – not more than 0.02 s, mass – 0.19 kg. The presented electromagnetic valves by their technical and operational characteristics meet the highest world requirements and have found wide utility in liquid rocket engines and propulsion systems.

Key words: electrohydraulic valve, electropneumatic valve, pneumohydraulic system, direct-action electric valve, electric valve with amplification, action time

Bibliography:
1. Electric Hydraulic Valve: Patent 89948 Ukraine: MPK F 16K 32/02 / Shnyakin V. M., Konokh V. I., Kotrekhov B. I., Troyak A. B., Boiko V. S.; Applicant and patent holder Yuzhnoye State Design Office. а 2006 02543; claimed 09.03.2006; published 25.03.2010, Bulletin No. 6.
2. Boiko V. S., Konokh V. I. Stabilization of Opening Time of Electric Hydraulic Valve with Boost in Liquid Rocket Engine Hydraulic System. Problems of Designing and Manufacturing Flying Vehicle Structures: Collection of scientific works. 2015. Issue 4 (84). P. 39-48.
3. Electric Valve: Patent 97841, Ukraine: MPK F 16K 32/02 / Shnyakin V. M., Konokh V. I., Kotrekhov B. I., Troyak A. B., Boiko V. S., Ivashura A. V.; Applicant and patent holder Yuzhnoye State Design Office. а 2009 12002; claimed 23.11.2009; published 26.03.2012, Bulletin No. 6.
4. Boiko V. S., Konokh V. I. Increase of Action Stability of Electric Pneumatic Valve with Boost in the System with Increased Inlet Hydraulic Resistance. Aerospace Engineering and Technology: Scientific-Technical Journal. 2013. Issue 3 (100). P. 90-95.
5. Flying Vehicles Pneumatic Systems Units / Lyaskovsky I. F., Shishkov A. I., Romanenko N. T., Romanenko M. T., Chernov M. T., Yemel’yanov V. V. / Under the editorship of N. T. Romanenko. М., 1976. 176 p.
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5.2.2018 Electromagnetic Valves Developed by Yuzhnoye SDO Liquid Rocket Engines Design Office
5.2.2018 Electromagnetic Valves Developed by Yuzhnoye SDO Liquid Rocket Engines Design Office
5.2.2018 Electromagnetic Valves Developed by Yuzhnoye SDO Liquid Rocket Engines Design Office

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3.2.2018 Possible Ways of Modernization of VEGA Launch Vehicle AVUM Stage Main Engine Assembly https://journal.yuzhnoye.com/content_2018_2-en/annot_3_2_2018-en/ Thu, 07 Sep 2023 08:42:19 +0000 https://journal.yuzhnoye.com/?page_id=30733
, Konokh V. , Dibrivny O. Enhancing the capabilities of payload injection by launch vehicles into various orbits of artificial Earth satellites is the main task for the developers of ILV as a whole and for the developers of separate assemblies and systems, such as LRE being part of ILV. Shnyakin V., Shul’ga V., Zhivotov A., Dibrivny A. Development status and improvement methods for upper stage engines of Vega and Cyclone launch vehicles. V., Konokh V. I., Kovalenko A. M., Dibrivny O. V., Konokh V. I., Kovalenko A. M., Dibrivny O. V., Konokh V. I., Kovalenko A. M., Dibrivny O. V., Konokh V. I., Kovalenko A. M., Dibrivny O. V., Konokh V. I., Kovalenko A. M., Dibrivny O. V., Konokh V. I., Kovalenko A. M., Dibrivny O.
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3. Possible Ways of Modernization of VEGA Launch Vehicle AVUM Stage Main Engine Assembly

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2018 (2); 16-24

DOI: https://doi.org/10.33136/stma2018.02.016

Language: Russian

Annotation: The Ukrainian companies Yuzhnoye SDO and SE PA YMZ supply VG143 main engine assembly for Vega LV AVUM upper stage, which is a one-chamber LRE of 250 kg thrust with five ignitions in flight. By the present, 11 successful launches of Vega LV have been made. In the process of flight operation, there were no critical comments on engines operation. This LRE has a combination of attractive characteristics, such as high specific pulse, low mass, multiple ignitions in flight, high reliability confirmed by good results of flight test of the prototype engines. The reserve of this engine from the viewpoint of further modernization is far from being exhausted. Enhancing the capabilities of payload injection by launch vehicles into various orbits of artificial Earth satellites is the main task for the developers of ILV as a whole and for the developers of separate assemblies and systems, such as LRE being part of ILV. With consideration for the experience of prototype engines testing, we should note the following ways of main engine assembly modernization: – increasing the specific pulse due to the increase of nozzle expansion ratio; – decreasing the volume of internal manifolds and mass of chamber; – increasing the operation time; – increasing the ignitions number; – increasing the duration of pauses between ignitions and orbital functioning time. Increasing the thrust and specific pulse of Vega LV VG143 main engine assembly and AVUM stage takes place due to the use of pneumopump propellant feeding system instead of standard pressure feeding. Besides, the information is presented on RD859, RD864, RD866 and RD869 prototype engines, the data on their basic characteristics, testing and operation. The below information is of interest to LRE and LV developers.

Key words: main engine assembly, liquid rocket engine, ways of modernization, engine chamber

Bibliography:
1. Shnyakin V., Shul’ga V., Zhivotov A., Dibrivny A. Creating a new generation of space-craft liquid rocket engines basing on pneumopump propellant supply systems. Space Propulsion: International Conference. France, Bordeaux. 2012.
2. Shul’ga V. Development status and improvement methods for upper stage engines of Vega and Cyclone launch vehicles. Space Propulsion; International Conference. Germany, Cologne. 2014.
3. De Rose L., Parmigiani P., Shnyakin V., Shulga V., Pereverzyev V., Caramelli F. Main engine of the Vega fourth stage: characteristics and heritage. 4th International Conference on Launcher Technology “Space Launcher Liquid Propulsion”. Netherlands, Noordwijk. 2018.
4. Kovalenko A. N., Pereverzev V. G., Marchan R. A., Blishun Y. V. Experimental Confirmation of Feasibility of Improving Power-Mass Characteristics of LRE for Vega Launch Vehicle Upper Stage: Paper presentation at the International Scientific-Technical Conference. S. P. Korolev SGAU, 2014.
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3.2.2018 Possible Ways of Modernization of VEGA Launch Vehicle AVUM Stage Main Engine Assembly
3.2.2018 Possible Ways of Modernization of VEGA Launch Vehicle AVUM Stage Main Engine Assembly
3.2.2018 Possible Ways of Modernization of VEGA Launch Vehicle AVUM Stage Main Engine Assembly

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14.1.2017 Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve https://journal.yuzhnoye.com/content_2017_1/annot_14_1_2017-en/ Wed, 28 Jun 2023 11:39:18 +0000 https://journal.yuzhnoye.com/?page_id=29497
Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve Authors: Boiko V. As a result of the investigations, the calculated dependencies were obtained that enable evaluating the design parameters impact on valve opening time when designing an electrohydraulic valve of given type. Kotelnikov. Shnyakin, V. Konokh, B. Available at: . Boiko V. Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve Автори: Boiko V. Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve Автори: Boiko V.
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14. Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2017 (1); 88-94

Language: Russian

Annotation: The configuration is considered of direct-action electrohydraulic valve ensuring wider operating range of the working fluid flow rate and pressure. The mathematical model of electrohydraulic valve is presented and the computational investigations of dynamic characteristics were performed. As a result of the investigations, the calculated dependencies were obtained that enable evaluating the design parameters impact on valve opening time when designing an electrohydraulic valve of given type.

Key words:

Bibliography:
1. Flying Vehicles Pneumatic Systems Units / I. F. Lyaskovsky, А. I. Shishkov, N. T. Romanenko, М. Т. Romanenko, М. Т. Chernov, V. V. Yemel’yanov; Under the editorship of N. T. Romanenko. М., 1976. 176 p.
2 Rotmansky O. I. Space Flying Vehicles Reaction Control Systems Valves / O. I. Rotmansky, I. R. Krichker. М., 1980. 136 p.
3. Useful Model Patent 95379 Russian Federation, MPK F16K32/02. Electromagnetic Stop Valve (Options) / Applicants and patent holders V. V. Zakharenkov, V. I. Kotelnikov. №2010106035/22; Claimed 19.02.2010; Published 20.08.2014, Bulletin No. 23. 4 p.: il.
4. Roters G. Electromagnetic Mechanisms. М., 1949. 522 p.
5. Patent 89948 Ukraine, MPK F16K32/02. Electrohydraulic Valve / V. M. Shnyakin, V. I. Konokh, B. I. Kotrekhov, А. B. Troyak, V. S. Boiko; Applicant and patent holder Yuzhnoye State Design Office, Dnipropetrovsk. а 2006 02543; Claimed 09.03.2006; Published 25.03.2010, Bulletin No. 6. 4 p.: il.
6. Gutovsky M. V. Reference Book on Designing and Calculation of Aviation Electric Equipment Elements / М. V. Gutovsky, V. F. Korshunov. М., 1962. 165 p.
7. Mathematic Modeling of Liquid Rocket Engines Working Process / Е. N Belyayev, V. K. Chvanov, V. V. Chervakov; Under the editorship of V. K. Chvanov. М., 1999. 228 p.
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14.1.2017 Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve
14.1.2017 Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve
14.1.2017 Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve
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Editorial board-old https://journal.yuzhnoye.com/editorial-board-en-old/ Sat, 13 May 2023 16:40:20 +0000 https://test8.yuzhnoye.com/?page_id=26177
KASHANOV, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr EXECUTIVE EDITOR OF THE EDITORIAL BOARD V. KUSHNAREV Yangel Yuzhnoye State Design Office, Dnepr V. SIRENKO, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr V. KONOKH, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr A. LOGINOV, Yangel Yuzhnoye State Design Office, Dnepr G. MAKAROV, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr O. POTAPOV, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr A. SANIN, Doctor of Engineering Science, Professor, Oles Honchar Dnipro National University V. TKACHENKO, Yangel Yuzhnoye State Design Office, Dnepr V.
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Editorial board

EDITOR-IN-CHIEF

A. V. DEGTYAREV, Doctor of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr

DEPUTY EDITOR-IN-CHIEF

A. E. KASHANOV, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr

EXECUTIVE EDITOR OF THE EDITORIAL BOARD

V. P. SAVCHENKO, Yangel Yuzhnoye State Design Office, Dnepr

MEMBERS OF THE EDITORIAL BOARD

F. GRAZIANI, Professor and President of Aerospace, Rome
A. P. KUSHNAREV Yangel Yuzhnoye State Design Office, Dnepr
V. M. SIRENKO, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr
V. I. KONOKH, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr
A. N. LOGINOV, Yangel Yuzhnoye State Design Office, Dnepr
G. A. MAIMUR, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr
A. L. MAKAROV, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr
O. M. MASHCHENKO, Yangel Yuzhnoye State Design Office, Dnepr
A. V. NOVIKOV, Candidate of Engineering Science, Professor, Yangel Yuzhnoye State Design Office, Dnepr
A. M. POTAPOV, Candidate of Engineering Science, Yangel Yuzhnoye State Design Office, Dnepr
A. F. SANIN, Doctor of Engineering Science, Professor, Oles Honchar Dnipro National University
V. D. TKACHENKO, Yangel Yuzhnoye State Design Office, Dnepr
V. S. KHOROSHILOV, Doctor of Engineering Science, Professor, Yangel Yuzhnoye State Design Office, Dnepr
A. D. SHEPTUN, Doctor of Engineering Science, Docent, Yangel Yuzhnoye State Design Office, Dnepr

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