Search Results for “valve” – Collected book of scientific-technical articles https://journal.yuzhnoye.com Space technology. Missile armaments Fri, 21 Jun 2024 08:14:43 +0000 en-GB hourly 1 https://journal.yuzhnoye.com/wp-content/uploads/2020/11/logo_1.svg Search Results for “valve” – Collected book of scientific-technical articles https://journal.yuzhnoye.com 32 32 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. 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. 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.
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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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13.1.2018 On Selection of Materials for Creation of Modern LV Thermostating System Mating Hoses https://journal.yuzhnoye.com/content_2018_1-en/annot_13_1_2018-en/ Tue, 05 Sep 2023 06:52:56 +0000 https://journal.yuzhnoye.com/?page_id=30469
Investigation of Operability of Rubbers with Adhesion Additives in Rubber-Metal Valves.
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13. On Selection of Materials for Creation of Modern LV Thermostating System Mating Hoses

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine1; State Enterprise DINTEM Ukrainian Research Design-Technological Institute of Elastomer Materials and Products2

Page: Kosm. teh. Raket. vooruž. 2018 (1); 72-84

DOI: https://doi.org/10.33136/stma2018.01.072

Language: Russian

Annotation: A series of materials is proposed for creation of space launch vehicle low-pressure air thermostating systems joints hoses. The topical issues are considered of materials designing with consideration for specific features of the hoses as special industrial rubber articles of launch vehicle launch sites.

Key words:

Bibliography:
1. Raw Stuff and Materials: Inf. Bull. М., 1999. No. 1. 44 p. https://doi.org/10.1007/978-1-4615-2802-9_3
2. Svitlichna R. F., Lotakov V. S., Chumicheva N. P. State and Prospects of Using Rubbers of New Generation in Rubber Industry of Ukraine: Scientific-Technical Report. К., 2001. No. 3. 13 p.
3. Nesterova L. A., Reznichenko S. V., Noskova L. F. et al. Experience of Using BNKS Paraffinate Nitrile Rubber in Formulations of Oil-Resistant Rubbers of Various Purpose at JSC “Uralsky Zavod RTI”. Med. Conf. on rubber: Collection of abstracts. М., 2000. No. 4. 121 p.
4. Investigation to Select Optimal Options of Replacing Raw Materials and Rubbers with Specifying Guaranteed Service and Storage Life of Rubber Products Being Components of Special Articles: Scientific–Technical Report DO-473-2002 UNUKTI DINTEM SE. 2002. 47 p.
5. Raw Stuff and Materials: Inf. Bull. М., 1999. No. 5. 55 p.
6. Raw Stuff and Materials: Inf. Bull. М., 2001. No. 3. 90 p.
7. Raw Stuff and Materials: Inf. Bull. М., 2001. No. 3. 96 p.
8. Raw Stuff and Materials: Inf. Bull. М., 2000. No. 3. 43 p.
9. Lotakov V. S., Yevchik V. S., Utlenko E. V. et al. Investigation of Operability of Rubbers with Adhesion Additives in Rubber-Metal Valves. Manufacture of Tires, Rubber Products and ATI. М., 1980. No. 4. P. 43-44.
10. Lotakov V. S., Yevchik V. S., Markova L. A. et al. Investigation of Alkali Impact on Adhesive Properties of Ethylene-Propylene Vulcanizing Agents. Caoutchouc and Rubber: Scientific–Technical Report. UNIKTI-DINTEM SE. 1981. No. 6. P. 18-19.
11. Svitlichna R. F., Bogutska E. O., Lotaakov V. S. et al. Technical Carbon of N Series. Prospects of Using in Rubber Mixtures of Caoutchoucs of New Generation: Scientific–Technical Report. К., 2006. No. 3. P. 17-20.
12. Yevchik V. S., Bogutskaya E. A., Khorolsky M. S. Investigations to Select Optimal Options of Replacing Raw Materials and Rubbers with Specifying Guaranteed Service and Storage Life of Rubber Products Being Components of 11K77 Article: Scientific–Technical Report DO-468-2000, UNIKTI-DINTEM SE. 2000. 55 p.
13. Nudelman Z. N., Lavrova L. N. Effective Vulcanization of Fluorine Rubbers. The III Ukr. International Scientific-Technical Conference of Rubber Industry Workers: Collection of abstracts. Dnepropetrovsk, 2000. 43 p.
14. Semyonov G. D., Yevchik V. S., Zaitseva T. P., Lotakov V. S. Prospects of Using New Vulcanizing Systems in Rubber Mixtures Based on Fluoroelastomers: Scientific–Technical Report. К., 2001. No. 3. 18 p.
15. Yevchik V. S., Zaitseva T. P., Khorolsky M. S. Investigations of Physical-Mechanical Characteristics of Rubbers Based on Caoutchoucs of New Generation: Scientific–Technical Report DO-387-89, DF VNIIEMI. Dnepropetrovsk, 2000. 61 p.
16. Belozerov N. V. Rubber Technology. М., 1979. 201 p.
17. Blokh G. A. Organic Rubber Vulcanization Accelerators. М.,1964. 156 p.
18. Big Reference Book of Rubber Industry Worker in 2 parts. Part 1. Rubbers and Ingredients / Under the general editorship of S. V. Reznichenko and Y. L. Morozov. М., 2012. 740 p.
19. Polyurethane Chemistry and Technology: Collection of conference papers. Manchester, 1967. 254 p.
20. Degteva T. G. et al. The Impact of Additives on Thermal Ageing of Rubbers and Model Gaskets Made of SKEP. Caoutchouc and Rubber. М., 1984. No. 8. P. 17-19.
21. Lepetov V. A. Rubber Products. L., 1976. 440 p.
22. Lepetov V. A., Yurtsev L. N. Calculations and Designing of Rubber Products and Production Accessories. М., 2009. 417 p.
23. New Prospective Hoses and Scarce and Commercially Inviable Rubbers, Ingredients and Materials: Recommendation No. 51-РМ-22/38/57/50-1050-83. М., 1983. 42 p.
24. Kornev A. E. et al. Technology of Elastomer Materials. М., 2009. 504 p.
25. Gerasimenko A. А. Protection of Machines from Biological Damages. M., 1984. 92 p.
26. Principles of Constructing Formulations and Using Rubbers for Rubber Products of Tropical Version: Recommendation No. 51-РМ-26-48-66. М., 1966. 56 p.
27. Assessment of Rubber Resistance to Damage by Thermites: Recommendation No. 51-РМ-4-622-75. М., 1975. 36 p.
28. Increasing Rubber Products Service Life in Conditions of Tropical Climate: Recommendation No. 51-РМ-4-697-76. М., 1976. 23 p.
29. Assessment of Rubber Resistance to Mould: Recommendation No. 51-РМ-4-407-73. М., 1976. 42 p.
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13.1.2018 On Selection of Materials for Creation of Modern LV Thermostating System Mating Hoses
13.1.2018 On Selection of Materials for Creation of Modern LV Thermostating System Mating Hoses
13.1.2018 On Selection of Materials for Creation of Modern LV Thermostating System Mating Hoses
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22.2.2017 Advanced Aluminum Alloys for Launch Vehicle Pipeline Parts Manufacture https://journal.yuzhnoye.com/content_2017_2/annot_22_2_2017-en/ Wed, 09 Aug 2023 12:36:11 +0000 https://journal.yuzhnoye.com/?page_id=29944
Closed Regulating Valves.
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22. Advanced Aluminum Alloys for Launch Vehicle Pipeline Parts Manufacture

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine1; Oles Honchar Dnipro National University, Dnipro, Ukraine2.

Page: Kosm. teh. Raket. vooruž. 2017 (2); 127-130

Language: Russian

Annotation: The comparison has been made of mechanical characteristics based on yield strength values of prospective aluminum alloys and steels with the stresses arising in pipeline parts. The conclusions have been drawn about the principal feasibility of manufacturing the pipelines of given materials and replacing the steels with the high-strength aluminum alloys for majority of the parts.

Key words:

Bibliography:
1. Davydov S. A. Analysis of Overall Dimensions of Launch Vehicle Pipeline Parts from Viewpoint of their Manufacturing by Method of Indirect Extrusion on Vertical Presses / S. A. Davydov, О. V. Bondarenko, Y. V. Tishchenko. System Designing and Analysis of Aerospace Hardware Characteristics: Collection of scientific works / Science Editor A. S. Davydov, Doctor of Engineering Science. Dnipropetrovsk, 2015. P. 23-28.
2. Alekseyev Y. S. Space Rocket Flying Vehicles Manufacturing Technology: Tutorial / Y. S. Alekseyev, E. O. Dzhur, О. V. Kulik, L. D. Kuchma, E. Y. Nikolenko, V. V. Khutorny / Under the editorship of E. O. Dzhur, Doctor of Engineering Science. Dnipropetrovsk, 2007. 480 p.
3. Birger I. A., Iosilevich B. G. Threaded and Flange Connections. М., 1990. 368 p.
4. Timoshenko S. P. Platelets and Shells / Translation from English V. I. Kontovt. М., L., 1948. 460 p.
5. GOST 19749-84. Fixed Detachable Connections of Pnemohydraulic Systems. Closed Regulating Valves. Types and Technical Requirements. М., 1984. 21 p. (USSR State Standards).
6. Bondarenko О. Sealing of Pipelines Flange Connections in Conditions of Fasteners Tightening Torgue Reducing / O. Bondarenko, A. Dziub. Applied Mechanics and Materials. Vol. 630 (2014). Switzerland: Trans tech Publications, 2014. P. 283-287.
7. Bondarenko O. V. Preliminary Determination of Geometrical Dimensions of Bellows Made of Aluminum Alloys / О. V. Bondarenko, Y. K. Demchenko. System Designing and Analysis of Aerospace Hardware Characteristics: Collection of scientific works / Science Editor A. S. Davydov, Doctor of Engineering Science. Dnipropetrovsk, 2016. P. 3-8.
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22.2.2017 Advanced Aluminum Alloys for Launch Vehicle Pipeline Parts Manufacture
22.2.2017 Advanced Aluminum Alloys for Launch Vehicle Pipeline Parts Manufacture
22.2.2017 Advanced Aluminum Alloys for Launch Vehicle Pipeline Parts Manufacture
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15.2.2017 Oxidizer Feedline Structural Optimization Results https://journal.yuzhnoye.com/content_2017_2/annot_15_2_2017-en/ Wed, 09 Aug 2023 12:10:23 +0000 https://journal.yuzhnoye.com/?page_id=29846
2017 (2); 77-82 Language: Russian Annotation: Two design options of manifold and dividing valve are considered, the loss calculation by analytical and numerical methods has been made. Hydrodynamic Characteristics of Regulating Valves and Pipeline Elements.
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15. Oxidizer Feedline Structural Optimization Results

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2017 (2); 77-82

Language: Russian

Annotation: Two design options of manifold and dividing valve are considered, the loss calculation by analytical and numerical methods has been made. Based on the calculation results, the optimal design option has been selected. The calculation correctness is confirmed as a result of development tests of the design.

Key words:

Bibliography:
1. Idel’chik I. E. Guide on Hydraulic Resistances / Under the editorship of M. O. Steinberg. 3rd edition revised and enlarged. М., 1992. 672 p.
2. Yan’shin B. I. Hydrodynamic Characteristics of Regulating Valves and Pipeline Elements. М., 1965. 259 p.
3. Gurevich D. F. Calculation and Designing of Pipeline Fittings: Calculation of Pipeline Fittings. 5th edition. М., 2008. 480 p.
4. Frenkel N. Z. Hydraulics. М., L., 1956. 451 p.
5. Reference Book on Hydraulics, Hydraulic Machines, and Hydraulic Actuators / Under the editorship of B. B. Nekrasov. Minsk, 1985.
6. Alyamovsky A. A. “Solid Works” Computer Modeling in Engineering Practice. Saint Petersburg, 2012. 445 p.
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15.2.2017 Oxidizer Feedline Structural Optimization Results
15.2.2017 Oxidizer Feedline Structural Optimization Results
15.2.2017 Oxidizer Feedline Structural Optimization Results
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14.2.2017 Development Test of Isolating Valve Operation under Cryogenic Conditions https://journal.yuzhnoye.com/content_2017_2/annot_14_2_2017-en/ Wed, 09 Aug 2023 11:38:09 +0000 https://journal.yuzhnoye.com/?page_id=29842
Development Test of Isolating Valve Operation under Cryogenic Conditions Authors: Makarenko A. 2017 (2); 70-76 Language: Russian Annotation: The paper is about the ground tests to refine the action dynamics of dividing valve operating in liquid oxygen environment. (2017) "Development Test of Isolating Valve Operation under Cryogenic Conditions" Космическая техника. "Development Test of Isolating Valve Operation under Cryogenic Conditions" Космическая техника. quot;Development Test of Isolating Valve Operation under Cryogenic Conditions", Космическая техника. Development Test of Isolating Valve Operation under Cryogenic Conditions Автори: Makarenko A. Development Test of Isolating Valve Operation under Cryogenic Conditions Автори: Makarenko A. Development Test of Isolating Valve Operation under Cryogenic Conditions Автори: Makarenko A. Development Test of Isolating Valve Operation under Cryogenic Conditions Автори: Makarenko A.
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14. Development Test of Isolating Valve Operation under Cryogenic Conditions

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2017 (2); 70-76

Language: Russian

Annotation: The paper is about the ground tests to refine the action dynamics of dividing valve operating in liquid oxygen environment.

Key words:

Bibliography:
1. Thermodynamics and Heat Transfer / A. V. Bolgarsky, G. A. Mukhachyov, V. K. Shchukin. М, 1964. 458 p.
2. Thermodynamics of Variable Gas Amount / Under the editorship of N. M. Belyayev. Dnepropetrovsk, 1981. 110 p.
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14.2.2017 Development Test of Isolating Valve Operation under Cryogenic Conditions
14.2.2017 Development Test of Isolating Valve Operation under Cryogenic Conditions
14.2.2017 Development Test of Isolating Valve Operation under Cryogenic Conditions
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13.2.2017 Experience in Development of Isolating Fuel Valve with Pneumatic Drive and Hydraulic Brake for Operation under Cryogenic Conditions https://journal.yuzhnoye.com/content_2017_2/annot_13_2_2017-en/ Wed, 09 Aug 2023 11:35:12 +0000 https://journal.yuzhnoye.com/?page_id=29836
Experience in Development of Isolating Fuel Valve with Pneumatic Drive and Hydraulic Brake for Operation under Cryogenic Conditions Authors: Makarenko A. 2017 (2); 65-69 Language: Russian Annotation: To support ignition of Taurus LV first stage core structure engine, an oxidizer dividing valve has been developed that ensures minimal hydraulic resistance, opening time and hydraulic impact. The paper considers the valve design, main phases of its ground development testing and basic critical comments on the design made in the process of manufacturing and testing. Report on the Results of Isolation Valve Check Tests Taurus-II.21.17039.203ОТ / Yuzhnoye SDO. Report on the Results of Isolation Valve Check Tests Taurus-II.21.17050.203ОТ / Yuzhnoye SDO. Report-Conclusion on the Results of Isolation Valve Developmental Tests 2TRS2S1.94.7204.0000.0000.00.0 ОЗ / Yuzhnoye SDO. (2017) "Experience in Development of Isolating Fuel Valve with Pneumatic Drive and Hydraulic Brake for Operation under Cryogenic Conditions" Космическая техника.
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13. Experience in Development of Isolating Fuel Valve with Pneumatic Drive and Hydraulic Brake for Operation under Cryogenic Conditions

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2017 (2); 65-69

Language: Russian

Annotation: To support ignition of Taurus LV first stage core structure engine, an oxidizer dividing valve has been developed that ensures minimal hydraulic resistance, opening time and hydraulic impact. The paper considers the valve design, main phases of its ground development testing and basic critical comments on the design made in the process of manufacturing and testing.

Key words:

Bibliography:
1. Report on the Results of Isolation Valve Check Tests Taurus-II.21.17039.203ОТ / Yuzhnoye SDO. Dnepropetrovsk, 2011. 30 p.
2. Report on the Results of Isolation Valve Check Tests Taurus-II.21.17050.203ОТ / Yuzhnoye SDO. Dnepropetrovsk, 2011. 23 p.
3. Report-Conclusion on the Results of Isolation Valve Developmental Tests 2TRS2S1.94.7204.0000.0000.00.0 ОЗ / Yuzhnoye SDO. Dnepropetrovsk, 2011. 161 p.
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13.2.2017 Experience in Development of Isolating Fuel Valve with Pneumatic Drive and Hydraulic Brake for Operation under Cryogenic Conditions
13.2.2017 Experience in Development of Isolating Fuel Valve with Pneumatic Drive and Hydraulic Brake for Operation under Cryogenic Conditions
13.2.2017 Experience in Development of Isolating Fuel Valve with Pneumatic Drive and Hydraulic Brake for Operation under Cryogenic Conditions
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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. 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. Space Flying Vehicles Reaction Control Systems Valves / O. Electromagnetic Stop Valve (Options) / Electrohydraulic Valve / V. (2017) "Design Studies into Dynamic and Structural Characteristics of Two-Stage Direct-Action Solenoid-Operated Hydraulic Valve" Космическая техника.
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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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9.1.2017 Mathematical Simulation of Gas-Jet Control System Distributor for Launch Vehicles https://journal.yuzhnoye.com/content_2017_1/annot_9_1_2017-en/ Tue, 27 Jun 2023 12:09:02 +0000 https://journal.yuzhnoye.com/?page_id=29434
Calculation and Investigation of Safety and Relief Valves.
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9. Mathematical Simulation of Gas-Jet Control System Distributor for Launch Vehicles

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2017 (1); 59-66

Language: Russian

Annotation: The differential equations of the gas-jet control system two-stage hot gas distributor are considered.

Key words:

Bibliography:
1. Belyayev N. M., Uvarov E. I. Calculation and Designing of Spacecraft Reaction Control Systems. М., 1974. 200 p.
2. Volkov E. B., Golovkov L. T., Syritsin Т. А. Liquid Rocket Engines. М., 1970. 592 p.
3. Abramovich G. N. Applied Gas Dynamics. М., 1976. 888 p.
4. Mamontov M. A. Some Cases of Gas Flowing in Pipes, Heads and Flow Vessels. М., 1951. 469 p.
5. Gerz E. V., Kreinin G. V. Dynamics of Pneumatic Actuators of Automatic Machines. М., 1964. 233 p.
6. Flying Vehicle Control System Pneumatic Actuators / V. A. Chashhin, О. Т. Kamladze, А. B. Kondrat’yev et al. М., 1987. 248 p.
7. Simakov N. N. Experimental Confirmation of Early Critical Region on Single Sphere. Journal of Technical Physics. Vol. 80, Issue 7. 2010.
8. Deich М. Е. Technical Gas Dynamics. М.-L., 1961. 412 p.
9. Sitnikov B. T., Matveyev I. B. Calculation and Investigation of Safety and Relief Valves. М., 1972. 127 p.
10. Danilov Y. A., Kirillovsky Y. L., Kolpakov Y. G. Equipment of Massive Hydraulic Actuators: Operating Processes and Characteristics. М., 1990. 272 p.
Downloads: 35
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9.1.2017 Mathematical Simulation of Gas-Jet Control System Distributor for Launch Vehicles
9.1.2017 Mathematical Simulation of Gas-Jet Control System Distributor for Launch Vehicles
9.1.2017 Mathematical Simulation of Gas-Jet Control System Distributor for Launch Vehicles
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15.2.2016 A New Method of Testing Oil-Filled Current Transformers for Explosion-Proofness https://journal.yuzhnoye.com/content_2016_2-en/annot_15_2_2016-en/ Tue, 06 Jun 2023 12:04:16 +0000 https://journal.yuzhnoye.com/?page_id=28331
2016 (2); 92-97 Language: Russian Annotation: The results of tests of high-voltage measuring current transformers TFRM with discharge valves and reinforced porcelain cover, in which transformer oil is used as internal insulation, by means of explosive blasting simulating short circuit inside current transformer, are under consideration.
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15. A New Method of Testing Oil-Filled Current Transformers for Explosion-Proofness

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2016 (2); 92-97

Language: Russian

Annotation: The results of tests of high-voltage measuring current transformers TFRM with discharge valves and reinforced porcelain cover, in which transformer oil is used as internal insulation, by means of explosive blasting simulating short circuit inside current transformer, are under consideration.

Key words:

Bibliography:
Downloads: 38
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645
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15.2.2016 A New Method of Testing Oil-Filled Current Transformers for Explosion-Proofness
15.2.2016 A New Method of Testing Oil-Filled Current Transformers for Explosion-Proofness
15.2.2016 A New Method of Testing Oil-Filled Current Transformers for Explosion-Proofness
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10.2.2016 Mathematical Model of High-Flowrate Electropneumatic Valve https://journal.yuzhnoye.com/content_2016_2-en/annot_10_2_2016-en/ Tue, 06 Jun 2023 11:57:58 +0000 https://journal.yuzhnoye.com/?page_id=28321
Mathematical Model of High-Flowrate Electropneumatic Valve Authors: Boiko V. 2016 (2); 65-71 Language: Russian Annotation: The developed mathematical model of electropneumatic valve, taking into account gas flow inertia in pneumatic pipelines, is under consideration. High convergence of test data with calculation results is obtained, making it possible to apply the developed mathematical model for evaluation of transient parameters, when electropneumatic valve operates in high flow-rate pneumatic system. (2016) "Mathematical Model of High-Flowrate Electropneumatic Valve" Космическая техника. "Mathematical Model of High-Flowrate Electropneumatic Valve" Космическая техника. quot;Mathematical Model of High-Flowrate Electropneumatic Valve", Космическая техника. Mathematical Model of High-Flowrate Electropneumatic Valve Автори: Boiko V. Mathematical Model of High-Flowrate Electropneumatic Valve Автори: Boiko V.
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10. Mathematical Model of High-Flowrate Electropneumatic Valve

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2016 (2); 65-71

Language: Russian

Annotation: The developed mathematical model of electropneumatic valve, taking into account gas flow inertia in pneumatic pipelines, is under consideration. High convergence of test data with calculation results is obtained, making it possible to apply the developed mathematical model for evaluation of transient parameters, when electropneumatic valve operates in high flow-rate pneumatic system.

Key words:

Bibliography:
Downloads: 39
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10.2.2016 Mathematical Model of High-Flowrate Electropneumatic Valve
10.2.2016 Mathematical Model of High-Flowrate Electropneumatic Valve
10.2.2016 Mathematical Model of High-Flowrate Electropneumatic Valve
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