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Studies have shown the presence of sulfur fractions in gasoil: total sulfur - 485 ppm (under the maximum allowed under GOST 52050-2006). In addition, the presence of gasoil of methyl - (0.237 ppm) and ethylmerkaptans (0.167 ppm) was revealed.
The Yurubchen gasoil also contained a small amount of 1 -octadekanethiol. It was found during the analysis of sulfuric acid fraction extract through chromatography-mass spectrometry (GC/MS) (H2SO4,93 %extraction, dilutingthe extract with water, re-extraction diethyl ether). Organic sulfides were not present in the extract.
The corrosiveness of the Yurubchen oil light fractions results from the content of hydrogen sulfide, mercaptans, and elemental sulfur.
The initial presence of thiols (merkaptans) in the petroleum is usually low. In the Yurubchen oil, there was only ethylmerkaptan at a concentration of0.136 ppm (GOST 50802 «Petroleum. Method for determination hydrogen sulfide, methyl and ethylmercaptans»).
Oil containing thiols is characterized by a high content of thiol and total sulfur in gasoline fractions with relatively
low content of the total sulfur in the original oil. For the Yurubchen oil, the following ratio could be observed: the total oil sulfur - 0.196 %, total gasoline (naphtha) sulfur -
0.0345%(GOSTR51947-2002 «Petroleumandpetroleum products. Sulfur identification by the method for energy-dispersive X-ray fluorescence spectrometry»).
Hydrogen sulfide, mercaptans and elemental sulfur formed the Yurubchen oil gasoil as secondary decomposition products of organic sulfur compounds underthermal impact in the process of distillation.
Hydrogen sulfide is released under oil heating up to 120 °C and higher; the amount of hydrogen sulfide increases with elemental sulfur, for example, as shown in the following reaction: RH + SkRSH 2RSH k RSR+H2S Based on the aforementioned research in conclusion we imply a possibility of additional methods for treatment (removal of elemental sulfur, demercaptanisation (sweetening), alkaline extraction ofhydrogen sulfide), in order to adjust the fraction quality indices in accordance with the requirements of GOSTR52050-2006.
© Bezborodov Ju. N., Nadeykin I. V., Orlovskaya N. F., Shupranov D. A., 2009
V A. Levko, M. A. Lubnin, P. A. Snetkov, E. B. Pshenko, D. M. Tunlov Siberian State Aerospace University named after academician M. F. Reshetnev, Russia, Krasnoyarsk
RESEARCH THE INFLUENCE FINISHING CANAL SHAPE TO FLOW MEDIA FOR ABRASIVE FLOW MACHINING PROCESS*
Visual research flow media nature as with abrasive tool put in to practice. To establish facts the influence degree finishing canal shape and form losses for flow character. The guidelines for processing environment leveling developed.
Keywords: abrasive flow machining, improved surface quality, flow of abrasive media, visual research, form losses,
cross-sectional shaped.
The analysis of constructional features of aircraft’s details has revealed the presence wide nomenclature of passageways with cross sections of various shapes and the presence of different local resistances like blades, form losses, etc.28 standard elements with different geometrical shape of cross sections, which can be found in aircraft, were discovered.
The main purpose of visual research was the fixing the process of abrasive media flowing in channel’s different configuration and its flowing of different local resistances, and the fixing of pressure media’s measurement Input P1 and output P2 sample.
The device was for the visual studies (fig. 1).It consists ofthebody 1 ,in whichthe groove set specimens-simulators
2, caps 3 and two adapters 4 and 5.
For the experiments the media was used with this composition: Silicon rubber (GOST 14680-74) - 48 %, PTFE-4 - 2 %; black silicon carbide 53 C (grain size = 250 microns) - 50 %. Visually, the media of this composition
has a dark gray color. On its surface, placed in a device, rectangular mesh size 15x15 mm and a depth of 2 mm, which is filled with white fused 25A with grain size = 250 microns, applied by the bursting pattern. White mesh has a good contrast with the surface of media, which provides a clear picture. The Scheme of application (fig. 2) simulates a chain of abrasive grains. Filming was carried out with a speed of 48 frames per second at high contrast, negative film.
Based on studies of the flow on the waveform, film, photographs and scratches at the window 6 of Plexiglas identified characteristics of media, evaluated and the degree of deformation grid on, and direct observation of the flow. Figure 3 shows the flow patterns and schemes of the media in the tested channels. The arrows indicate the direction of flow, a dark color - the stagnant zone.
Each sample has a definite influence on the flow, the value of which can be expressed by the coefficient of local resistance &
& = & + c/Re,
=cg 1 c 7
* The work within the federal purpose program “Scientific, scientific-pedagogical cadres Innovative Russia”.
where &cg - coefficient of configuration geometry flow; yc - dimensionless velocity gradient; Re - the Reynolds number.
7
b
Fig. 1. Fixture for visual research off abrasive flowmachining: a - casing with model; b - fixture diagram
Fig.2. The grid on the surface environment, modeling the chain of abrasive grains
Forthe case ofAFMyc = 0.01...0.1 andRe << 1. Itcan take &m - &cg. Consequently, the coefficient &cg characterizing the flow pressure loss in passing through this channel will determine the amount of local losses flux in AFM, i. e.
6 - PJPr
^cg 1 2
Studies show that the greatest pressure loss experienced in the flow cone channels (№ 5...7). The coefficient &c takes valuesof20.0...23.5.
Toothing with 12 triangular channels (№ 28) creates a pressure differential 5.2. For channels with different blades (№ 17...26) &cgvariesfrom 1.8to2.1.
When processing channels with a small inlet (№ 3, 4) pressure loss is reduced more than twice, but the magnitude ofthe coefficient&cg - 8.4...10.0 remains significant. Ifthe inlet channels with a small inlet is rounding or chamfer (№ 8,9), the value & reducedto3.4...3.7.
cg
For channels with local resistance (№ 10...15)the value has avalue of1.4...3.0 depending onthe type of resistance. Forthe three parallel channels (№ 16) the pressure drop was 2.3.
These values & can be used to assess the influence of
cg
the channel cross section shape and type of local resistance to the pressure drop of the working environment at AFM. The value & in this case is relative, because it does not take
cg
into account the pressure loss along the length of the sensor
7 to the sample and from sample to the sensor 8 (fig. 1).
Figures № 4...12 show photographs illustrating the content of the film process medium flow through some of the samples. The direction of flow from left to right.
Sample number 1 (fig. 4) is a local narrowing the channel from the direct gap of half-cylinder. At the initial moment the flow in the center of the channel environment without encountering obstacles, begins the process of shear flow in a half-cylinder. Thus there is a deformation of the grid -elongation of the axis of flow and contraction in the transverse direction. In those places where the environment rests on the front side surface of the sample, the flow of environment is not present.
At this point in the environment the profile of media is changing and two zones with different conditions of deformation are formed. In the zone of shear flow observed steady shear flow. The character of variation of the grid shows a gradient flow, which can be described by the hydrodynamic theory. Stress of elastic chaincanbe describedby the Kargin-Slonimsky-Rouse models [1].
In the second zone there is compression of the chain. The magnitude of compression depends on the elastic properties of the chain. Thus, inthe mediumtwo zones with different conditions of deformation are forming. In the first zone tensile stress is observed, in the second zone -compression stress.
When reaching a certain critical value, there is a shift environment in zone 1 on the medium in zone 2. Clearly the boundary between zones 3 is visible. At this point flow profile finally formed and in zone 1 tensile stress drops into the shear flow 4. This transition is clearly apparent in the oscillogram.
Then all of a large part of the media is fond of Zone 2 in the flow when the piston moving in the working cylinder. However, just before the obstacle in zone 2 of stagnation zone is formed. In the sample stagnation zoneis not formed,
Fig.3. Scheme of the flow media in the channels of Designs
contact the media is carried out over the entire surface of the sample. The use of leveling devices is not required.
At the end of the medium the sample the effect of elastic recovery of the jet is observed, which is indicating accumulated in the flow of elastic deformations. This effect is described in detail previously [2]. Especially this effect is clearly manifested at the expiration of the channels of small dimensions, such as in samples number 3, 4 and 5.
If withinthe medium in conical ducts withvariable crosssection flow pattern different. Consider the flow in a diffuser - sample number 6 (fig. 5) and in effuser - sample number 7 (fig. 6). Uneven treatment due to the nature of shear flow environment inthe conical channel.
Whenthe mediumflow inthe diffusernoticeable decrease in the rate of the conical part and a smooth restructuring of the flow profile. The normal stresses accumulate, and the tangent decrease. The pressure in the conical part increases and the flow rate and velocity gradient decreases. In steady the maximum flow pressure on the wall of the channel observed in the cross section with a minimum size, ie on the exit edge of the channel. If such a motion is possible to provide a uniform flow of the processing and removal of metal within a specified allowance in the cylindrical part of the channel.
At the entrance flow in a conical part effuser channel in the initial moment of time there is separation of high-flow environment of the tunnel wall. This phenomenon is a relatively short period of time 0.2...1.1 seconds.
At the same time, in the medium relaxation of accumulated stress occurs and the effect of elastic recovery of the jet begins to manifest itself, i. e. increase in its size and the gradual filling of the total volume of processed feed.
Instant transition from anguish to the free flowjet is for transition edge. At this point, the value of relaxation of elastic strain accumulated in the medium during the flow in the cylindrical part, is maximal. At the edge of the transition, there is a maximum pressure of the flow on the wall of processed feed.
The uniformity of treatment in the conical channel equalization without using special devices to make difficult, since the change in flow profile is directly processed channels. In the special case of flow can be identified based AFM unidirectional diffuser.
In flying apparatus there are details of structural elements, which canbe attributed to local resistance. Inthese studies, these are examples of resistance number 10 ... number 15.
Channel flow with the lateral wall (fig. 7), characterized by displacement of the medium flow 4 from the central axis of the channel. In this case the inlet there are not two, but three dead zone 2. Two are inlet channel and one is front wall. Behind the observed flow separation from the wall of the treated feed. Because of the effect of elastic recovery is gradually filling the entire volume of the test channel, including and beyond the partition. After completing this section of the channel environment it appears dead space. The bulk of the flow slides along the border of this zone. Processed only the surface of walls, which is parallel to the main stream.
Another form of local resistance, which appears in the details of flying apparatus, is a rectangular resistance at the inlet and outlet channels (fig. 8).
Peculiarity of the flow in this sample is to divide the flow into two parts. Forming two zones of dilation 1 and three
Fig. 5. The process flow in sample number 6 (cone)
compression zone 2. Two of these zones are located on the side of the entrance to the processed feed, and another - on the front surface of the rectangular resistance. Afterthe start of shear flow formed two zones within 4 to form the output of the channel bands of elastic recovery 5.
Details of the flying apparatus are characterized by the presence of several parallel arranged relative to each other channels, with identical geometric characteristics. Figure 9 shows that the flow profile is formed at the entrance to the channels. On the flat front edges of the channels formed stagnant zones. Expendable Pressure-flow characteristics in the channels are almost identical.
Various blades are the basic structural elements of aircraft and rackets parts. Inthe studies presented samples ofblades number 17... number26.
The flow in straight rectangular channel with a sloping shoulder blade with a straight forward basis (sample number
17) is shown in Figure 10. Blade breaks straight rectangular channel into two parts with variable cross-section shape. In this case, in the channels among modes of deformation are different. In having a smaller area of the inlet the expanding part ofthechannelobserveddeformationzone 1 elongationmedium.
In having a greater cross section of the inlet of a shrinking part of the channel in the central part of the observed elongation zone, which is to the walls of the channel is replaced by a zone of compression. Stagnant zone 2 observed on the surfaces perpendicular to the main direction of deformation of the medium.
After adjustment profile in the zones of tensile strain -compression of the deformation of 4 shear flow environment with the subsequent effect of elastic recovery 5. The main processing occurs in sections with a smaller area.
Another flow pattern is observed inAFM’s environment inclined channel with sloping shoulders. Flow of the medium
Fig. 7. The process flow in the sample number 10 (bulkhead)
Fig. 8. The process flow in the sample number 11 (obstruction at the entrance)
rJW''
Fig. 9. The process flow in the sample number 16 (parallel channels)
in an inclined channel with a sloping shoulder blade with a straightforwardreason- samplenumber19(fig. 11). Since the investigated channel has an angle of inclination relative to the central axis of the working cylinder, and changing the directionofflow.
Restructuring flow profile environment is at the entrance to the processed feed. There two dead zone 2 and two zones of dilation 1 are forming. After reaching a critical value in zones 1 strain is replacedby a shearflow intwo parts, the channel also implemented a process of shear flow in zones 4 with subsequent elastic restoration of the environment in zone 5.
Flow separation with a sharp front edge is not observed. The entire surface of the channel is processing except for a direct cause shoulder at the entrance to the channel. The size of the stagnation zone 2 during the entire process of processing does not change.
In a separate group of flying apparatus parts are structural elements that have a large channel L length and small cross-
section S with ratio L/S >> 1. When flow through a small cross section (fig. 12) inthe channel has created a complex grains, preventing the flow shear.
The piston operating cylinder could not provide the necessary amount of shear stress and there was jamming Abrasives. For AFM such channels must use the abrasive medium special formulations with reduced viscosity.
According to the research design elements on the processing conditions can be divided into five groups.
The first group includes channels with constant cross section (№ 1.. 4, 8, 9, 28), which does not affect the flow. They have small values of the coefficient of the configuration flow &cg. Chamfer at the entrance to the channel (№ 8) provides a smooth entry into the media channel, reducing the coefficient &cg. Since the channel with beveled (№ 8) &cg = 3.4 less than in this channel (№ 9) with a facet at the output &cg = 3.7. For such channels adjustment stress-strain state of flux carried by a special technique.
Fig. 10. The process flow in the sample number 17
The second group of cone channels, the loss of pressure medium in which the maximum. For the uniform treatment of such channels is recommended to change the flow regime of thecone to ring slit (№ 5...7) orto apply a one-way AFM (№ 6).
In the third group, consisting of a channel with the local resistance, AFM’s still rough surface, perpendicular to the flow (№ 10...15). For processing to change the direction of flow through the leveling devices.
For a uniform treatment of channels with blades, which are the fourth group (№ 16...26), it is necessary to ensure an even flow environment in each of the channels, by forming the flow profile at the entrance of these channels.
In the fifth group included micro, requiring the use of working environments with low effective viscosity and low dispersion of abrasive filler (№ 27).
In analyzing the motion of individual abrasive grains in a flow is established that they move along the current lines. In steady flow the distance between neighboring grains is not changed. This confirms the supposition about the formation of elastic chains inthe flow [1]. Establishedthatthe grain, into contact withthe treated surface, the flow performs rotational motion. Studies education media vortices near walls orinthe flow with the flow in the channel was not observed.
Research has identified the nature of the flow in channels of different media configurations and taken into account in calculatingthe roughness of the surface finishandperformance of AFM on the previously developed technique [3].
Bibliography
1. Левко, В. А. Модель течения рабочей среды при абразивно-экс^узиожой обработке тонких осесимметричных каналов большой длины / В. А. Левко // Вестн. Чебоксар гое. пед. ун-та. Механика недельного состояния : сб. науч. тр. / под ред. акад. Д. И. ^вдева; Ч^аш. гос. пед. ун-т. Чебоксары, 2008. № 2. С. 85-94.
2. Левко, В. А. Абразивно-экс^узионная обработка: современный уровень и теоретические основы процесса : монография / В. А. Левко ; Сиб. гос. аэрокосмич. ун-т. Красноярск, 2007.228 с.
3. Левко, В. А. Расчет шероховатости поверхности при абразивно-экструзионной обработке на основе модели контактных взаимодействий / В. А. Левко // Авиационная техника. Известия вузов / под ред. проф. В. А. Фирсова ; Казан. гос. техн. ун-т. 2009. № 1. С. 59-62.
© Levko V. A., Lubnin M. A., Snetkov P. A., Pshenko E. B., Turilov D. M., 2009
P. A. Snetkov, V. A. Levko, E. B. Pshenko, M. A. Lubnin Siberian State Aerospace University named after academician M. F. Reshetnev, Russia, Krasnoyarsk
EXPERIMENTAL DETERMINATION FACTOR TO VISCOSITY, ELASTICITY AND PLASTICITY MEDIA FORABRASIVE FLOW MACHINING PROCESS*
Numerical values of factors of viscosity, elasticity and plasticity of a media are established. Experimental dependences of viscosity and elasticity of environment on degree of its filling and granularity of abrasive grains are revealed.
Keywords: abrasive flow machining, rheological characteristics, viscoelastic media, flowable abrasive particles, shear rate.
The one of the new types of such processing is abrasion-extrusion processing (AFM), which is consist in removing the layer of material from the surface of the treated channel at extruding under pressure through it, working environment, consisting of a viscosity and elasticity foundation, filled of solid working elements (most often - abrasive or diamond grains).
AFM is difficult process. In its implementation there are a number of physical phenomena that influence for quality and productivity of processing. For the introduction of abrasive extrusion processing in the production of specific details must be made a sufficiently large volume of experimental studies, related with determining the optimum composition of the working environment and modes of its extrude, caused by physical-mechanical and geometrical characteristics of processed channels. Such researching
needs a lot of costs, which constituting up to 60 % of the total cost of implementing this technology in production.
The main parameters of technological process of abrasive extrusion processing is the volume of the working environment, pressure of the hydraulic system installation in burst and the host operating cylinder of installations for AFM, value (dispersion) and percentage (concentration) of abrasive grains in the working environment, its physical and mechanical characteristics, and also the numberof processing cycles. The geometric characteristics of the processed feed have great influence on the quality and productivity of the process - its radius and length, area and perimeter of the cross-sectional and also initial physical and chemical properties of the surface layer.
Cutting ability of the working environment as abrasive tools depends of flow’s conditions in the processed channel
* The work within the federal purpose program “Scientific, scientific-pedagogical cadres Innovative Russia”.
