Vandyshev A.B. Kulikov V.A. Example of Design Calculation of a Membrane-Catalytic Device for Production of High-Purity Hydrogen from Hydrocarbon Raw Materials // Chemical and Petroleum Engineering. 2022. Vol. 57. Nos. 9-10. P. 740-746. [10.1007/s10556-022-01001-7].
Vandyshev A.B. Kulikov V.A. Analysis of Parameters for Producing High-Purity Hydrogen from Natural Gas in a Tubular Type Membrane-Catalytic Module // Chemical and Petroleum Engineering. 2021. Vol. 56. Nos. 9-10. P. 715-720. DOI: 10.1007/s10556-021-00833-z.
Vandyshev A.B. Kulikov V.A. Assessment of the Effect of Hydrocarbon and Steam Mixture Flow Rate on the Main Parameters of High-Purity Hydrogen Production in a Membrane-Catalytic Device with a Fixed Membrane Area // Chemical and Petroleum Engineering. 2021. Vol. 57. Nos. 7-8. P. 639-646. DOI: 10.1007/s10556-021-00989-8.
Vandyshev A.B. Kulikov V.A. Assessment of the Effects of Temperature and Pressure on the Efficiency of High-Purity Hydrogen Production from Hydrocarbon Feedstocks in Membrane-Catalytic Devices // Chemical and Petroleum Engineering. 2021. Vol. 56. No. 9-10. P. 799-808. DOI: 10.1007/s10556-021-00845-9.
Vandyshev A.B. Kulikov V.A. Analysis of Membrane and Membrane-Catalytic Systems for Producing High-Purity Hydrogen from Ammonia // Chemical and Petroleum Engineering. 2019. Vol. 55. No. 1-2. P. 43-50. DOI: 10.1007/s10556-019-00581-1.
Vandyshev A.B. Kulikov V.A. Analysis of the Design Calculation of a Membrane-Catalytic Converterf or Producing High-Purity Hydrogenf rom Biodiesel Fuel // Chemical and Petroleum Engineering. 2019. Vol. 55. No. 3-4. P. 209-215. DOI: 10.1007/s10556-019-00607-8.
Vandyshev A.B. Kulikov V.A. Analysis of the Efficiency of a Pd/Ag Membrane with a Thickness of 2.25 Microns on a Porous Ceramic Substrate in a laboratory Membrane Reactor // Chemical and Petroleum Engineering. 2019. Vol. 55. No. 1-2. P. 31-37. DOI: 10.1007/s10556-019-00592-y.
Vandyshev A.B. Kulikov V.A. Analysis of the results of testing an individual disk-type membrane-catalytic module for obtaining high-purity hydrogen from methane // Chemical and Petroleum Engineering. 2019. Vol. 55. No. 9-10. P. 725-732. DOI: 10.1007/s10556-020-00686-y.
Vandyshev A.B. Kulikov V.A. Evaluation of design parameters for a 32-module disk-type membrane-catalytic reactor for producing high-purity hydrogen from diesel fuel // Chemical and Petroleum Engineering. 2019. Vol. 55. No. 9-10. P. 815-820. DOI: 10.1007/s10556-020-00698-8.
Vandyshev A.B. Kulikov V.A. Analysis of the Calculated parameters of a Model Membrane-Catalytic Converter for the Production of High-Purity Hydrogen from Methane. // Chemical and Petroleum Engineering. 2018. Vol. 54. No. 1-2. P. 31-37. DOI: 10.1007/s10556-018-0434-y.
Vandyshev A.B. Kulikov V.A. Modeling a Membrane Reformer with a Carbon-Monoxide Conversion Catalyst for Extracting High-Purity Hydrogen from Methane Steam-Conversion Products // Chemical and Petroleum Engineering. 2018. Vol. 54. Nos. 5-6. P. 313-321. DOI: 10.1007/s10556-018-0481-4.
Vandyshev A.B. Kulikov V.A. Estimate of High-Purity Hydrogen Production Efficiency in Membrane-Catalytic-Systems from Reforming Products of Gasoline, Kerosene, and Diesel Oil // Chemical and Petroleum Engineering. 2017. Vol. 53. No. 9-10. P. 592-597. DOI: 10.1007/s10556-018-0386-2.
Vandyshev A.B. Kulikov V.A. Analysis of Parameters and Modes for Producing High-Purity Hydrogen from Natural Gas in Membrane-Catalytic Devices // Chemical and Petroleum Engineering. 2017. Vol. 53. – No. 1-2. P. 49-55.
Vandyshev A.B. Kulikov V.A. Energy and Resource Efficience in Industrial Systems for Production and Use of High-Purity Hydrogen // Chemical and Petroleum Engineering. 2017. Vol. 53. – No. 3-4. P. 166-170.
Vandyshev A.B. Kulikov V.A. Analysis of parameters of high-purity hydrogen production from methane in a laboratory-scale membrane reformer with an ultrathin palladium membrane // Chemical and Petroleum Engineering. 2015. Vol. 51, Nos. 3-4. P. 250-256. DOI 10.1007/s10556-015-0032-1.
Vandyshev A.B. Kulikov V.A. Hydrogen Permeability of Palladium Membranes Made of Alloy V-1 in Laboratory Investigations And Membrane Devices // Chemical and Petroleum Engineering. 2015. Vol. 51, Nos. 5-6. P. 396-401. DOI 10.1007/s10556-015-0058-4.
Vandyshev A.B. Kulikov V.A. Calculating the main parameters of a Membrane Reformer with a Production Rate of 40 m3/h Designed for Producing Highly Pure Hydrogen from Natural Gas [Electronic resource] // Diagnostics, Resource and Mechanics of materials and structures. 2015. Is. 3. P. 109-121. URL: http://dream-journal.org/issues/2015-3/2015-3_31.html.
Vandyshev A.B. Kulikov V.A. Preparation of specially pure hydrogen from dimethyl ester in a high-temperature converter-membrane equipment system with catalytic conversion of CH4 or CO in the space above a membrane // Chemical and Petroleum Engineering. 2014. Vol. 49, No 9-10. P. 660-667.
Vandyshev A.B. Kulikov V.A. Comparison of calculated and experimental flow data for a membrane reformer for special-purity hydrogen production from natural gas // Chemical and Petroleum Engineering. 2014. V. 49. – Nos. 9-10. P. 660-667.
Vandyshev A.B. Kulikov V.A. Preparation of specially pure hydrogen from dimethyl ester in a high-temperature converter-membrane equipment system with catalytic conversion of CH4 or CO in the space above a membrane // Chemical and Petroleum Engineering. 2014. V. 49. – Nos. 11-12. P. 719-726.
Vandyshev A.B. Kulikov V.A. Extraction of extra pure hydrogen from methan steam conversion products in membrane equipment, combined simultaneously with two CO and CH4 conversion catalysts // Chemical and Petroleum Engineering. 2012. Vol. 47, No 11-12 (march). P. 831-836.
Vandyshev A.B. Kulikov V.A. Evaluation of the efficiency of preparing especially pure hydrogen from methanol and ethanol in membrane equipment, combined with a methane or carbon monoxide conversion catalyst // Chemical and Petroleum Engineering. 2011. Vol. 47, Nos. 7-8. P. 536-544.
Vandyshev A.B. Kulikov V.A. Major ways of enhancing efficiency and economy of membrane method of special-purity hydrogen production from natural gas // Chemical and Petroleum Engineering. 2010. Volume 46, Numbers 11-12. P. 726-733.
Vandyshev A.B. Kulikov V.A. Nikishin S.N. Analysis of flow-rate characteristics of high-output membrane equipment for the production of ultra-pure hydrogen // Chemical and Petroleum Engineering. 2010. Volume 46, Numbers 1-2. P. 72-78.
Vandyshev A.B. Kulikov V.A. Nikishin S.N. Raising efficiency of special-purity hydrogen production from nitrogen-hydrogen gas mixtures // Chemical and Petroleum Engineering. 2009. Volume 45, Numbers 5-6. P. 360-363.
Vandyshev A.B. Kulikov V.A. Nikishin S.N. Raising efficiency of super-pure hydrogen production from natural gas // Chemical and Petroleum Engineering. 2008. Volume 44, Numbers 7-8. P. 382-386.
Vandyshev A.B. Kulikov V.A. Murav’ev L. L. Nikishin S. N. Ozone disinfection of water for bathing pools of recirculation type // Chemical and Petroleum Engineering. 2007. Volume 43, Numbers 1-2. P. 108-112.
Vandyshev A.B. Kulikov V.A. Nikishin S.N. Increase in the efficiency of preparing specially pure hydrogen from methane in a high-temperature converter-membrane equipment system // Chemical and Petroleum Engineering. 2007. Volume 43, Numbers 11-12. P. 660-666.
Vandyshev A.B. Kulikov V.A. Kirnos I. V. Nikishin S.N. High-temperature membrane apparatuses in systems for repeated utilization of hydrogen // Chemical and Petroleum Engineering. 2006. Volume 42, Numbers 11-12. P. 640-644.
Makarov V.M. Kulikov V.A. Vandyshev A.B. Investigation of the process of continuous production of solid caustic soda in “sharp” jet apparatus // Chemical and Petroleum Engineering. 1999. Volume 35, Number 3. P. 142-146.
Kulikov V.A. Vandyshev A.B. Makarov V.M. Study of the operation and method of calculating the injector for feeding a “Strong” gas-liquid jet // Chemical and Petroleum Engineering. 1998. Volume 34, Numbers 9-10. P. 547-550.
Baryshnikov V. V. Bukin V. V. Vandyshev A.B. Komarskikh A. V. Kulikov V.A. Apparatus for ozone treatment of circulating water // Chemical and Petroleum Engineering. 1997. Volume 33, Number 6. P. 699-702.