Your search keyword '"ejection coefficient"' showing total 21 results

1. 基于EBF神经网络的引射器结构参数优化.

Author

么大锁, 赵凯芳, 吴国鹏, 季宁, and 裴毅强

Abstract

Copyright of Machine Tool & Hydraulics is the property of Guangzhou Mechanical Engineering Research Institute (GMERI) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

2. Mathematical Modeling of Jet Aeration Process for Ecological Purification of Ponds

Author

Akhmetov, Vadim, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Akimov, Pavel, editor, and Vatin, Nikolai, editor

Published

2022

3. Improving the Energy Efficiency of the Use of Oil Jet Pumps

Author

D. A. Panevnyk

Subjects

borehole jet pump, ejection system, pump efficiency, pump energy characteristic, flow mixing, ejection coefficient, relative head, Hydraulic engineering, TC1-978, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The substantiation of the choice of design parameters characterizing the mutual orientation of the mixed flows and the ratio of the geometric dimensions of the elements of the flow path of the jet pump that provide an increase in the energy characteristics of borehole ejection systems is given. Depending on the mutual orientation of the mixed flows, three variants of the design of the jet pump are possible, viz. the one with a parallel orientation of the working and ejected flows, the one with the inlet of the ejected flow at a sharp angle, and the one with a perpendicular orientation of the working and ejected flows. The magnitude of the angle between the velocity vectors of the mixed flows directly affects the intensity of vortex formation in the mixing chamber, the amount of energy loss and the efficiency of the jet pump; however, the simplicity of their manufacture remains the determining condition for choosing the design variant of the elements of ejection systems. Based on the use of the laws of conservation of energy, the amount of motion and continuity of the flow, it is determined that the level of energy loss during mixing flows is directly proportional to the magnitude of the angle of entry of the ejected medium. In the course of computer simulation of the jet pump workflow, an asymmetric distribution of hydrodynamic parameters for the non-parallel orientation of the mixed flows has been obtained. In order to reduce energy losses when mixing flows, the value of the angle of entry of the ejected flow must be taken in the range from 0 to 15°. In the case of the implementation of the zero head mode and the maximum ejection coefficient, minimal energy losses during mixing of flows are provided for the main geometric parameter of the jet pump equal to 2.375. In the course of experimental studies, the inverse dependence of the maximum value of the efficiency of a borehole jet pump on the value of its main geometric parameter represented as a power function, has been established. When using ejection systems that implement long-term technological processes (e. g., during oil production), it is necessary to take the minimum possible value of the main geometric parameter of the jet pump for the specified operating conditions.

Published

2022

4. Verification of the analytical design model of a subcritical air ejector and assessment of the behavior of the manufactured machine under different operating conditions.

Author

Honus, Stanislav, Jadlovec, Marek, Šmída, Zdeněk, Výtisk, Jan, and Vrtek, Mojmír

Subjects

*BEHAVIORAL assessment, *COMPUTATIONAL fluid dynamics, *FLOW coefficient, *TURBULENCE, *TURBULENT flow, *NOZZLES

Abstract

Ejectors are dynamic energy machines that can be designed using analytical methodologies that have been in use for decades. These calculation methods consist of coefficients and equations, which are now untraceable and have not been updated since they were first proposed. Modern literature is devoid of ejector design; therefore, to conduct research on ejectors, it is first necessary to verify the validity of existing computational methods. In this study, we conducted computational fluid dynamics (CFD)-assisted experiments to simulate a subcritical air-to-air ejector with the possibility of controlling the distance of the nozzle mouth from the mixing chamber inlet. It was found that the optimum distance of the nozzle mouth from the mixing chamber inlet (i.e. 7.9 mm) corresponds to the design condition when the ejection coefficient is 1.673 and the secondary medium quantities reach the maximum value of 31.19 kg/h. A change in the position of the nozzle outside the optimum point leads to a deviation in the ejection coefficient and flow rate. The experimental results were compared with those from CFD analysis and the deviation between them did not exceed 2%. Two turbulent flow models, namely k–Ω BSL and k–ε standard, were used for the comparison. [ABSTRACT FROM AUTHOR]

Published

2022

5. Improving the Energy Efficiency of the Use of Borehole Jet Pumps

Author

D. A. Panevny and A. V. Panevny

Subjects

ejector technologies, ejection system, pump efficiency, hydraulic system, working point of the pump unit, ejection coefficient, cavitation in the jet pump, Hydraulic engineering, TC1-978, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The article presents rationales for choosing the depth of installation of an oil jet pump in the borehole that which ensures maximum efficiency of its operation. The operating parameters of the ejection system are determined by the joint solution of the characteristic equations of the high-pressure jet pump and the hydraulic system. In the process of solving the system of equations, the method of successive approximations, the Delphi software environment and PTC Mathcad resources were used. The equation of the characteristics of the jet pump hydraulic system was obtained by determining the pressures in its distinctive cross-sections and then presenting their values as the relative (dimensionless) head of the ejection system. Alteration the installation depth of the jet pump changes the characteristics of its hydraulic system, the parameters of the operating point of the pumping unit and its efficiency. In this case, the minimum permissible installation depth of the jet pump is determined by the value of the minimum pressure in the elements of the ejection system, which must exceed the value of the elastic pressure of saturated vapors of the oil and gas flow and ensure its operation in pre-cavitation mode. The probability of operation of a jet pump in cavitation mode was studied using the Bernoulli, Darcy – Weisbach and flow continity equations. The inversely dependence of the ejection coefficient and efficiency of the jet pump on the depth of its installation in the borehole has been revealed. If the jet pump is installed in the borehole at the optimal depth, its efficiency is increased by 30 %.

Published

2020

6. 圆柱形混合室截面直径对喷射系数影响的实验研究.

Author

何丽娟, 王淑旭, 吴夏梦, and 王飒

Abstract

Copyright of Journal of Engineering for Thermal Energy & Power / Reneng Dongli Gongcheng is the property of Journal of Engineering for Thermal Energy & Power and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

7. IMPROVING EFFICIENCY OF THE JET PUMP AT LOW COEFFICIENTS OF EJECTION

Author

A. G. Butenko and S. Yu. Smik

Subjects

jet pump, ejection coefficient, mathematical modeling, Hydraulic engineering, TC1-978, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Jet pumps are widely used in the power industry as well as in many others. Their main disadvantage is low operating efficiency which aggravates when the jet pump is working with a low ejection coefficient. Such modes are sometimes unavoidable being conditioned by the character of technological process. The article considers methods of improving the operation of central ejectors at small ejection coefficients.The authors use mathematical simulation approach to study the particularities of kinematic structure of the flow in the mixing chamber of the central ejector operating with low ejection coefficients. They utilize Solid Works Cosmos Flo application-program package for the mathematical simulation. The study shows that areas of reverse flows appear alongside the walls of the mixing chamber under the above conditions which reduces the efficiency of the jet apparatus. The more is the extent of the discovered areas the more is the loss of energy. The study detects the regime zones where detached flows areas appear. The authors propose to replace such areas with solid surface (substitution bodies) for preventing them from emerging. The mathematical simulation results determine the geometric parameters of the substitution bodies for the central ejectors with different modules and ejection coefficients and yield mathematical description of their shape. Mathematical and physical simulation of the centralejector operation with the substitution bodies shows the increase in pressure-head and efficiency coefficients in such apparatuses as compared to ejectors of the conventional form. Efficiency increase is the case in quite a wide range of operating modes.The proposed method of the efficiency increase for the central ejectors is rather straightforward and does not require substantial financial expenditures for its implementation.

Published

2015

8. Features of the vapor formation process near a wall with a gas-droplet film cooling.

Author

Terekhov, V. I. and Shishkin, N. E.

Abstract

On the basis of available experimental data, we have performed an analytical study of the concentration of saturated vapor over a liquid film formed from droplets being deposited onto the wall of an adiabatic channel under gas-droplet film cooling. The analysis was carried out by varying the main parameters of the mixing jets, namely, the ejection coefficient, the concentration of the liquid, and the main-flow temperature. An approximating dependence for the concentration of saturated vapor in the presence of the liquid film is obtained, and the effect due to the flow nonisothermality is taken into account. [ABSTRACT FROM AUTHOR]

Published

2019

9. Ejectors for pressure recovery systems of supersonic chemical lasers.

Author

Malkov, V., Kiselev, I., Shatalov, I., Duk, A., and Emelyanova, A.

Abstract

Results of a numerical study of performance characteristics of supersonic ejectors with nozzles of different types are reported. The work was carried out with the aim of developing a high-performance ejector for pressure recovery systems of supersonic chemical lasers. A specific feature of the operation of ejectors in pressure recovery systems consists in that, in this case, the ejecting and ejected gases, as they undergo mixing, have different thermodynamic properties, and the ejection coefficient depends on the ratio between the temperatures of the gases and on the ratio of their molecular masses. Since the operation of an ejector is based on the mixing process, the task consisted in intensification of this process using nozzles of special geometries. The performance of ejectors was judged considering an integral parameter, the product of induction by compression ratio. The calculations of the 3D viscous gas flow in the ejector channel were performed using ANSYS software. In verifying the numerical model, a comparison with experimental data obtained earlier on a model ejector facility and during tests of real pressure recovery systems in operation with supersonic chemical lasers was performed. [ABSTRACT FROM AUTHOR]

Published

2017

10. A novel technology for optimizing dissolved air flotation unit efficiency via secondary saturation of the flotation cell with air bubbles and thin-layer settling.

Author

Andreev, Sergey Yu., Lebedinskiy, Konstantin V., and Stepanov, S.V.

Subjects

*DISSOLVED air flotation (Water purification), *LAMINAR flow, *TRANSLATIONAL motion, *ROTATIONAL motion, *FLUID flow, *WASTEWATER treatment

Abstract

• The operation of flotation units is possible due to the use of thin-layer lamellas. • The improvement of flotation units is achieved via secondary saturation of the chamber with bubbles. • The bubbles float in laminar flow regime, and light turbulence is created. • The bubbles are destroyed in the centrifugal field due to rotational and translational motion. • The use of two ejectors accommodates a stable air release from the atmosphere. Specific ways to improve the technology for flotation (DAF) wastewater treatment have been determined. Prospects to increase functioning of DAF units via using thin-layer cells, and improving the hydraulic size of the emerging flotation aggregates have been shown. The latter is feasible due to secondary saturation of the flotation cell with air bubbles of 0.1–0.3 mm diameter floating in laminar flow regime and creating light turbulence thereof. The possibility of obtaining an air-water mixture with air bubbles during their breaking up in the annular space of the saturator-separator is experimentally proven. It is feasible to separate the air bubbles from the major fluid flow in the centrifugal field due to rotational and translational motion of the separated mixture. It is established that converting the Q-H vane pump characteristics, which provides for pumped flow circulation and useful flow selection for the two medium-pressure ejectors operating in series, allows to: ensure stable air ejection from the atmosphere; significantly increase the vane pump head H via reducing the supplied useful flow; exclude a compressor and replace an expensive high-pressure pump with a lower operating pressure one. [ABSTRACT FROM AUTHOR]

Published

2023

11. IMPROVEMENT OF THE CENTRAL EJECTOR EFFICIENCY UNDER NONOPTIMAL OPERATING MODES.

Author

Butenko, A. H. and Smyk, S. Yu.

Abstract

Purpose. The study aimed the improvement of the central ejector efficiency under nonoptimal operating modes, in particular low coefficients of ejection. Methodology. The purpose of the study was implemented by means of mathematical modeling in the SOLID WORKS COSMOS FLO software environment and by experimental studies on the physical model. Findings. The data about kinematic structure of the stream in the mixing chamber of the central ejector were obtained. They showed that at low ratios of ejection the separation of the flow away from the walls occurs. A method of eliminating separation zones--replacing of their existence areas by hard surfaces was proposed. Originality. It was proved that separation zones arise under small coefficients of ejection in the mixing chamber of the central ejector. They are characterized by a high level of dissipative processes. On maintaining of these processes some part of mechanical energy of the stream is expended, leading to a decrease in efficiency of the ejector as a whole. The conditions of separation zones and their geometrical parameters were defined. It made possible to replace the area of their existence by solids introduced into the mixing chamber of the ejector. Mathematical and physical modeling showed improving of ejectors efficiency with replacement bodies within a wide range of operating modes. Practical value. Central ejectors are widely used in various industries. Their main drawback is poor performance. This is especially true when working in the low coefficients of ejection. The conducted studies have provided a way to improve efficiency of ejectors working in such conditions. The method is simple, economical, does not require additional operating costs; it can be implemented by the staff in manufacturing. [ABSTRACT FROM AUTHOR]

Published

2015

12. Analysis of a coaxial gas ejector.

Author

Sychenkov, V., Panchenko, V., and Khaliulin, R.

Abstract

In this paper, the results of investigating a coaxial gas ejector without increase of passive flow pressure are presented. A technique for calculation of coaxial ejectors has been developed. This investigation has resulted in the optimal structure of ejector with a high value of ejection coefficient. [ABSTRACT FROM AUTHOR]

Published

2014

13. Research of operation of liquid-gas ejectors with compact and dispersed jets of liquid

Author

Yaroslav Khitriy, Vitaly Ponomarenko, Dmitriy Liulka, Eugene Babko, and Nicholas Pushanko

Subjects

Engineering drawing, Materials science, ejection coefficient, locking mode, Liquid gas, Liquid jet, Drop (liquid), Nozzle, liquid-gas ejector, Injector, Mechanics, lcsh:Business, law.invention, dispersion flow of the liquid, law, lcsh:Technology (General), Emulsion, lcsh:T1-995, Underwater, lcsh:HF5001-6182, Mixing chamber

Abstract

The analysis of equipment for the sulfitation of sugar solutions is carried out. The shortcomings of the operation of a jet sulfitator are identified, for the elimination of which it is necessary to investigate the hydrodynamics of a two-phase flow in an ejector mixing chamber. An experimental setup is made. Ejectors with a compact and dispersed liquid jet are studied in a wide range of geometric characteristics (1.3...11.25). The range of the optimum geometric characteristic of the ejector (4...7) is established, at which the maximum ejection coefficient is reached. The numerical value of this coefficient depends on the supply pressure to the nozzle of the active jet and increases with its increase. At a liquid pressure on the nozzles P = 1.25·10 5 Pa, the ejection coefficient reaches a numerical value of 2.0. And the K ej for the ejector with a compact jet of liquid is 15...20 % lower than K ej for the ejector with a dispersed jet. The ejector locking mode is detected at low liquid feed pressures, which occurs when the resistances of the underwater gas path are equal and the movement of the water-air emulsion in the mixing chamber of the ejectors is equal. Explain the work of the ejector can be given the early crisis of drop resistance at small (Re≈40...130) values of the Reynolds criterion. For the investigated ejectors, the closing mode of the next one after the liquid supply pressure is 0.14...0.17 MPa.

Published

2017

14. Обгрунтування вибору геометричних розмірів свердловинного струминного насоса

Subjects

коэффициент эжекции, струминний насос, коефіцієнт корисної дії, oil well, эжекционная система, ejection system, ejection coefficient, нафтова свердловина, коэффициент полезного действия, камера змішування, ежекційна система, working nozzle, камера смешивания, diffuser, струйный насос, рабочая насадка, нефтяная скважина, jet pump, mixing chamber, efficiency factor, коефіцієнт ежекції, диффузор, робоча насадка, дифузор

Abstract

Запропонована методика вибору геометричних параметрів свердловинного струминного насоса, яка забезпечує його експлуатацію в режимі максимального коефіцієнта корисної дії. Відповідно до розробленого алгоритму регламентуються співвідношення діаметрів робочої насадки, камери змішування та дифузора струминного насоса, а також відстань між соплом та камерою вирівнювання швидкостей та осьові розміри елементів протічної частини. В процесі встановлення необхідних розмірів елементів ежекційної системи врахований характер входження вільного робочого струменю в камеру змішування струминного насоса, який визначає вигляд та структуру розрахункових співвідношень, що регламентують осьову відстань між робочою насадкою та камерою відновлення швидкостей змішуваних потоків. Показаний взаємозв’язок між співвідношенням діаметрів камери змішування і робочої насадки та величиною коефіцієнта ежекції струминного насоса, який забезпечує його роботу з максимально можливими значеннями ККД ежекційної системи. Аналітичний характер встановлення гідравлічних взаємозв’язків між елементами ежекційної системи доповнено досвідом практичного використання глибинних струминних насосів при реалізації окремих технологічних процесів будівництва, експлуатації та ремонту нафтових свердловин., Предложена методика выбора геометрических параметров скважинного струйного насоса, обеспе- чивающая его эксплуатацию в режиме максимального коэффициента полезного действия. В соответствии с разработанным алгоритмом регламентируются соотношения диаметров рабочей насадки, камеры смешивания и диффузора струйного насоса, а также расстояние между соплом и камерой выравнивания скоростей и осевые размеры элементов проточной части. В процессе определения необходимых размеров элементов эжекционной системы учитывался характер вхождения свободной рабочей струи в камеру смешивания струйного насоса, который определяет вид и структуру расчетных соотношений, регламентирующих осевое расстояние между рабочей насадкой и камерой восстановления скоростей смешиваемых потоков. Показана взаимосвязь между соотношением диаметров камеры смешивания и рабочей насадки и величиной коэффициента эжекции струйного насоса, который обеспечивает его работу с максимально возможными КПД эжекционной системы, Аналитический характер определения гидравлических связей между элементами эжекционной системы дополнен опытом практического использования глубинных струйных насосов при реализации отдельных технологических процессов строительства, эксплуатации и ремонта нефтяных скважин., The method of choosing geometric parameters of the well hole pump which ensures its operation in the mode of maximum efficiency is proposed. According to the algorithm developed, the ratio of the diameters of the working nozzle, the mixing chamber and the diffuser of the jet pump, as well as the distance between the nozzle and the speed equalization chamber and the axial dimensions of the flow part elements are regulated. During the process of establishing the required dimensions of the elements of the ejection system, the nature of the free working jet into the mixing chamber of the jet pump is taken into account, which determines the shape and structure of the estimated ratios governing the axial distance between the working nozzle and the resuscitation chamber of the mixing streams. The relationship between the mixing chamber diameters and the working nozzle and the amount of the jet pump coefficient of ejection which ensures its operation with the maximum possible values of the ejection system efficiency is shown. The analytical nature of the establishment of hydraulic interconnections among the elements of the ejection system is complemented by the experience of the practical use of deep jet pumps in the implementation of certain technological processes of construction, operation and repair of oil wells.

Published

2018

15. ЭЖЕКЦИЯ И ИНЖЕКЦИЯ РЕАГЕНТОВ В ТЕХНОЛОГИЯХ ВОДОПОДГОТОВКИ

Subjects

коэффициент эжекции, эжектор, хлорирование, chlorination, mixing chamber, ejection coefficient, диффузор, аэрация, ejector, камера смешения, diffuser, aeration

Abstract

Система водоподготовки предусматривает введение в нее различных реагентов. Основными технологическими способами внедрения реагентов в обеззараживаемую воду являются эжекция и инжекция. В данной статье проведен анализ этих методов. Разработана методика расчета высокопроизводительных эжекторов. Проведенными авторами лабораторные и производственные испытаниями установлены оптимальные соотношения продольных размеров внутреннего сечения, обеспечивающие максимально эффективное значение коэффициента эжекции., A water treatment system provides for the introduction of various reagents into it. The main technological methods for introducing reagents into disinfected water are ejection and injection. This article analyzes both of these methods. A technique for calculating high-efficiency ejectors is developed. The laboratory and production tests carried out by the authors established the best proportions of the internal section longitudinal dimensions – they ensure the maximum effective value of the ejection coefficient., Международный научно-исследовательский журнал, №08(62) (2017)

Published

2017

16. Исследование работы жидкостно-газовых эжекторов с компактной и диспергированной струей жидкости

Author

Ponomarenko, Vitaly, Pushanko, Nicholas, Khitriy, Yaroslav, Liulka, Dmitriy, and Babko, Eugene

Subjects

жидкостно-газовый эжектор, коэффициент эжекции, режим запирания, диспергированная струя жидкости, liquid-gas ejector, ejection coefficient, locking mode, dispersion flow of the liquid, рідинно-газовий ежектор, коефіцієнт ежекції, режим запирання, диспергований струмінь рідини, УДК 664.1.038, UDC 664.1.038

Abstract

The analysis of equipment for the sulfitation of sugar solutions is carried out. The shortcomings of the operation of a jet sulfitator are identified, for the elimination of which it is necessary to investigate the hydrodynamics of a two-phase flow in an ejector mixing chamber. An experimental setup is made. Ejectors with a compact and dispersed liquid jet are studied in a wide range of geometric characteristics (1.3...11.25). The range of the optimum geometric characteristic of the ejector (4...7) is established, at which the maximum ejection coefficient is reached. The numerical value of this coefficient depends on the supply pressure to the nozzle of the active jet and increases with its increase. At a liquid pressure on the nozzles P = 1.25·105 Pa, the ejection coefficient reaches a numerical value of 2.0. And the Kej for the ejector with a compact jet of liquid is 15...20 % lower than Kej for the ejector with a dispersed jet. The ejector locking mode is detected at low liquid feed pressures, which occurs when the resistances of the underwater gas path are equal and the movement of the water-air emulsion in the mixing chamber of the ejectors is equal. Explain the work of the ejector can be given the early crisis of drop resistance at small (Re≈40...130) values of the Reynolds criterion. For the investigated ejectors, the closing mode of the next one after the liquid supply pressure is 0.14...0.17 MPa., Проведено аналіз обладнання для сульфітації цукрових розчинів. Виявлено недоліки роботи струминного сульфітатора. Для встановлення закономірностей гідродинаміки двофазного потоку в камері змішування виготовлено експериментальну установку. Досліджувався ежектор з компактним та диспергованим струменем рідини. Встановлено оптимальну геометричну характеристику ежектора. Виявлено режим запирання за низьких тисків подачі рідини., Проведен анализ оборудования для сульфитации сахарных растворов. Выявлены недостатки работы струйного сульфитатора. Для установления закономерностей гидродинамики двухфазного потока в камере смешивания изготовлена экспериментальная установка. Исследован эжектор с компактной и диспергированной струей жидкости. Установлена оптимальная геометрическая характеристика эжектора. Выявлен режим запирания при низких давлениях подачи жидкости.

Published

2017

17. Characteristic of Turbocharger- Intercooler-Ejector System, an at Diesel Engine

Author

Lazarev, E.A. and Salov, A.Y.

Subjects

коэффициент эжекции, exhaust gases and air flow rates, ejection coefficient, эжектор, ejection charge air cooling system, система эжекционного охлаждения, УДК 621.436, flow characteristics, параметры газовых потоков, параметры охлаждающего воздуха, gas-jet ejector

Abstract

Лазарев Евгений Анатольевич, доктор технических наук, профессор кафедры «Двигатели внутреннего сгорания», Южно-Уральский государственный университет, г. Челябинск, lea2@mail.ru. Салов Андрей Юрьевич, аспирант кафедры «Двигатели внутреннего сгорания», Южно-Уральский государственный университет, г. Челябинск, s-1990@mail.ru. E.A. Lazarev, lea2@mail.ru, A.Y. Salov, s-1990@mail.ru South Ural State University, Chelyabinsk, Russian Federation Приведена методика расчета для системы, состоящей из турбокомпрессора, охладителя наддувочного воздуха и эжектора, установленного за турбиной. Она позволяет однозначно определить и связать давления и температуры воздуха и отработавших газов в основных сечениях проточной части компрессора и турбины с показателями эффективности элементов рассматриваемой системы на любом режиме работы дизеля. Исходными данными для расчета являются известные из проектного расчета геометрические размеры проходных сечений турбины, компрессора, эжектора, охладителя, а также текущие значения давления и температуры отработавших газов. Определены и рассчитаны характеристики подобной системы для дизеля серии 4Т. На внешней скоростной характеристике показаны изменения параметров отработавших газов перед турбиной и эжектором, наддувочного воздуха после компрессора и охладителя, охлаждающего воздуха перед эжектором, а также изменение степени повышения давления в компрессоре, степени понижения давления отработавших газов в турбине, мощности турбокомпрессора, расхода охлаждающего воздуха через охладитель и степени охлаждения наддувочного воздуха. В ходе расчета выявлена возможность регулирования системы на частичных режимах работы дизеля изменением площадей поперечного сечения сопла и камеры смешения эжектора. Также из условия достижения максимального коэффициента эжекции определен оптимальный закон изменения этих площадей при работе дизеля на частичных режимах. Для сравнения эффективности работы нерегулируемого и регулируемого эжекторов показаны изменения значений коэффициента эжекции для по внешней скоростной характеристике дизеля. Также численно смоделирована работа эжектора на разных режимах работы дизеля. Methods of calculating the characteristics of the system, consisting of a turbocharger, intercooler and ejector, which installed after the turbine. It allows to determine the parameters of the charge air before the valves at any operating mode of the diesel engine, as well as to find to find an ability to control of the ejector. Calculation allow one to relate the parameters listed devices and determine the parameters of the charge air, as well as other parameters, such as the power of the turbocharger and the pressure and temperature of the gases in the main sections of the compressor and turbine in any diesel engine operation. The initial data for this calculation are geometric dimensions of the turbine, compressor, ejector, intercooler, known in the design calculation and current values of the pressure and exhaust gas temperature. Shows the characteristics of such a system designed for diesel 4T series. On the full-load curve showing changes in temperature and exhaust gas pressure before the turbine and in front of the ejector, the pressure and temperature of the charge air downstream of the compressor and after cooling, the pressure and temperature of cooling air to the ejector, and changing the degree of pressure rise in the compressor, the degree of the exhaust gas pressure reduction in the turbine of the turbocharger power, cooling air flow through the cooler, the degree of cooling of the charge air.

Published

2016

18. The features and characteristic of gas-jet ejector charge air cooling system of diesel engine

Author

Lazarev, E. A., Salov, A. Yu., and Pomaz, A. N.

Subjects

коэффициент эжекции, exhaust gases and air flow rates, компрессор, охладитель типа «воздух-воздух», ejection coefficient, turbine, flow characteristics, charger, параметры газовых потоков, эжектор и его элементы, ГРНТИ 55.42, расходы газа и охлаждающего воздуха, gas-jet its components, УДК 621.436, турбина, air-to-air charge air cooler

Abstract

Рассмотрены функциональные и конструктивные особенности системы эжекционного охлаждения наддувочного воздуха в дизеле с газотурбинным наддувом. Определены параметры газовых потоков и их изменение в газовом эжекторе системы.The design features of gas-jet ejector charge air cooling system of supercharged diesel engine. Determine gas flow parameters and changes of flow in the gas ejector system. Лазарев Евгений Анатольевич. Доктор технических наук, профессор кафедры «Двигатели внутреннего сгорания», Южно-Уральский государственный университет (Челябинск), lea2@mail.ru. Салов Андрей Юрьевич. Аспирант кафедры «Двигатели внутреннего сгорания», Южно-Уральский государственный университет (Челябинск), s-1990@mail.ru. Помаз Андрей Николаевич. Аспирант кафедры «Двигатели внутреннего сгорания», Южно-Уральский государственный университет (Челябинск), a007007@yandex.ru. Е.А. Lazarev, South Ural State University, Chelyabinsk, Russian Federation, lea2@mail.ru, A.Y. Salov, South Ural State University, Chelyabinsk, Russian Federation, s-1990@mail.ru, A.N. Pomaz, South Ural State University, Chelyabinsk, Russian Federation, a007007@yandex.ru

Published

2014

19. Investigation of Multiphase Ejectors

Subjects

ежектор, коефіцієнт ежекції, камера змішання, дифузор, ejector, ejection coefficient, mixing chamber and diffuser, эжектор, коэффициент эжекции, камера смешения, диффузор

Abstract

Представлені результати чисельних і експериментальних досліджень ежекторів. Наведено розрахункові та експериментальні результати визначення коефіцієнта ежекції для газових і газорідинних ежекторів, які мають широке застосування в різних областях техніки. Визначено оптимальні геометричні параметри, що впливають на роботу ежектора і забезпечують більший коефіцієнт ежекції при менших втратах енергії активного потоку. Особливістю даних досліджень ежекторів полягає в тому, що тиск пасивного потоку і тиск на виході з ежектора рівні атмосферному тиску. При порівнянні результатів проектних досліджень з експериментальними даними спостерігається тісна зближність., Представлены результаты численных и экспериментальных исследований эжекторов.Приведены расчетные и экспериментальные результаты определения коэффициента эжекции длягазовых и газожидкостных эжекторов, которые имеют широкое применение в различных областяхтехники. Определены оптимальные геометрические параметры, влияющие на работу эжектора иобеспечивающие больший коэффициент эжекции при меньших потерях энергии активного потока.Особенностью данных исследований эжекторов заключается в том, что давление пассивного потока идавление на выходе из эжектора равны атмосферному давлению. При сравнении результатов расчетныхисследований с экспериментальными данными наблюдается близкая сходимость., The results of numerical and experimental investigations of the ejectors have been given. The computational and experimental results of the determination of the coefficient of ejection for gas and gas-liquid ejectors that are widely used in different spheres of the technology have been presented. Gas ejectors are particularly used for the reduction of the temperature field of the combustion products in gas turbine engines. Gas-liquid ejectors found broad application in the field of fire–fighting equipment, which is used for the generation of water–air jet and remote mixture delivery to fight the seats of fire. Optimal geometric parameters that effect the ejector operation and possess a high coefficient of ejection at reduced energy losses of active flow have been determined. The peculiarity of these investigations of the ejectors is that the passive flow pressure and ejector output pressure are equal to atmospheric pressure. The comparison of the results of calculated and experimental data shows their close convergence.

Published

2014

20. Investigation of multiphase ejectors

Subjects

коэффициент эжекции, ejection coefficient, mixing chamber, диффузор, ejector, камера смешения, diffuser

Abstract

Представлены результаты численных и экспериментальных исследований эжекторов. Приведены расчетные и экспериментальные результаты определения коэффициента эжекции для газовых и газожидкостных эжекторов, которые имеют широкое применение в различных областях техники. Определены оптимальные геометрические параметры, влияющие на работу эжектора и обеспечивающие больший коэффициент эжекции при меньших потерях энергии активного потока. Особенностью данных исследований эжекторов заключается в том, что давление пассивного потока и давление на выходе из эжектора равны атмосферному давлению. При сравнении результатов расчетных исследований с экспериментальными данными наблюдается близкая сходимость. The results of numerical and experimental investigations of the ejectors have been given. The computational and experimental results of the determination of the coefficient of ejection for gas and gas-liquid ejectors that are widely used in different spheres of the technology have been presented. Gas ejectors are particularly used for the reduction of the temperature field of the combustion products in gas turbine engines. Gas-liquid ejectors found broad application in the field of fire–fighting equipment, which is used for the generation of water–air jet and remote mixture delivery to fight the seats of fire. Optimal geometric parameters that effect the ejector operation and possess a high coefficient of ejection at reduced energy losses of active flow have been determined. The peculiarity of these investigations of the ejectors is that the passive flow pressure and ejector output pressure are equal to atmospheric pressure. The comparison of the results of calculated and experimental data shows their close convergence.

Published

2014

21. Energy and resource operating water-air jet pumps

Author

Spiridonov, E. K. and Ismagilov, A. R.

Subjects

степень сжатия, коэффициент эжекции, the degree of compression, давление питания, УДК 621.69, побудитель пассивного потока, диффузор, activator of inactive stream, УДК 621.51, relative area of the nozzle, УДК 527.4, относительная площадь сопла, back pressure, ejection coefficient, diffusion, phase slip coefficient, экстремальные характеристики, ограничительное условие, restrictive condition, extreme characteristics, струйный насос, jet pump, supply pressure, противодавление, давление в приемной камере, pressure in the reception chamber, коэффициент скольжения фаз

Abstract

Проанализированы пути оптимизации водовоздушного струйного насоса на основе экстремальных характеристик. Показано, что существенное повышение эффективности работы водовоздушного струйного насоса возможно за счет снижения противодавления, применения диффузора и побудителя пассивного потока. Предложено конструктивное решение по снижению давления за струйным насосом. The ways of optimization of the water-air jet vacuum pump on the basis of extreme performances are parsed. It is shown that essential growth efficiency of work of water-air jet pump is possible because decrease back pressure, use of diffusion and activator of inactive stream. Constructive decision for decrease pressure after jet pump is suggested. Спиридонов Евгений Константинович. Доктор технических наук, профессор, заведующий кафедрой «Гидравлика и гидропневмосистемы», декан аэрокосмического факультета, Южно-Уральский государственный университет. Область научных интересов – прикладная гидромеханика и гидравлика, струйные аппараты, лопастные насосы и напорные гидросистемы. E-mail: ggps@susu.ac.ru Evgeny K. Spiridonov. The doctor of engineering science, professor, the Head of «Hydraulics and hydropnevmosystems» department, Dean of Aerospace faculty of South Ural state university. Professional interests: applied hydromachanics and hydraulics, jet devices, lobe pumps and pressure head hydraulic circuit systems. E-mail: ggps@susu.ac.ru Исмагилов Александр Рашидович. Аспирант кафедры «Гидравлика и гидропневмосистемы», Южно-Уральский государственный университет. Область научных интересов – прикладная гидромеханика и гидравлика, струйные аппараты. E-mail: shura.ismagilov@yandex.ru Alexander R. Ismagilov. Postgraduate student of «Hydraulics and hydropnevmosistems» department of South Ural state university. Professional interests: applied hydromachanics and hydraulics, jet devices. E-mail: shura.ismagilov@yandex.ru

Published

2012