UA156160U - Bagatopoploviy gas ejector - Google Patents

Abstract

The gas ejector consists of an inlet nozzle and a diffuser body, in which an annular insert is placed, which has an annular pressure chamber with nozzle holes directed along the wall of the inner channel. Additionally, it contains a module of nozzles that are placed inside the ejector path and connected to the annular chamber by a pylon tube and directed at an angle to the ejector axis in the area between the nozzles of the annular insert.

Description

The useful model belongs to mechanical engineering, in particular, it concerns the production of aggregates and devices of automotive and aviation equipment and systems of technological lines.

The technical result is a reduction in overall parameters and an increase in the level of consumption and pressure characteristics.

The gas ejector is widely used in various fields of technology and technological lines due to its simple design, high reliability, and unlimited service life.

The main structural elements of a gas ejector: a high-pressure ejecting gas nozzle, a low-pressure ejecting gas nozzle, a mixing chamber and a diffuser. In the initial section of the chamber, ejected gas particles are continuously captured by the high-speed jet and transported by it to the mixing zone. Thanks to this, rarefaction at the entrance to the mixing chamber is maintained, which ensures the flow of low-pressure gas into the ejector. The relative consumption of the primary and secondary flows of this gas, which is called the ejection coefficient K, depends on the area of the nozzles, on the density of gases and their initial pressures, and on the mode of operation of the ejector.

A gas ejector of the traditional direct-flow scheme |1)| is known, in which a low-speed, ejected secondary flow is formed around the primary fully submerged high-speed jet.

One of the disadvantages of ejectors of the traditional scheme is that the length of the cylindrical mixing chamber is quite large and its optimal length is usually equal to the order of 10 calibers (21 at a relatively small value of the ejection coefficient.

In many technological systems and technical solutions, an ejector with small overall dimensions is needed, but at the same time one that has high consumption characteristics, a fairly high ejection coefficient and works at a high pressure of the ejecting gas. Reducing the length of the mixing chamber leads to a sharp drop in the ejection coefficient and device consumption parameters.

You can improve the characteristics of the device if you change the scheme of the gas-dynamic path.

An ejector using a supersonic jet as the ejecting gas flow is also known

IEZI. The design feature is that the nozzle - a slot for blowing a supersonic wall jet, was located on the inner surface of the wall at the beginning of the mixing chamber. The scheme of interaction of a high-speed semi-confined coaxial jet with a free secondary flow is implemented.

The peculiarity of such an ejector is the presence of a mixing chamber of variable cross-section along the length.

It consists of a short cylindrical insert at the beginning and an elongated diffuser. It combines the functions of mixing the primary and secondary jets and braking the flow at the exit of the ejector. Gas consumption at the outlet of such ejectors, under certain conditions, reaches a 20-fold excess over the corresponding parameter in the boost line. This indicator is much better than that of the ejector of the traditional type.

The disadvantage of the ejector of this type is that, although its length is 4-5 times shorter, compared to the classic scheme, it still remains quite large.

In addition, the attractive efficiency of such an ejector has a narrow range of relative parameters of the geometry of the internal gas-dynamic tracts, as well as the boost and exhaust pressures.

An attempt to improve the flow characteristics of an ejector with limited overall dimensions by increasing the boost pressure of the jet flowing out of the gap leads to its separation from the streamlined surface and, as a result, partial closure of the low-speed gas by the high-pressure jet |4)І. At the same time, the value of the ejection coefficient drops rapidly.

A significant drawback is a weak pressure.

The closest analog to a useful model is a gas ejector |5). A feature of the device is its use for releasing compressed air through a system of small nozzles placed on the inner wall of the mixing chamber. The ejector consists of an inlet nozzle and a diffuser body connected by bolts.

An annular insert is placed in the housing, which has an annular pressure chamber with holes-nozzles directed along the wall of the inner channel.

When jets flow out at high speed from a package of directional nozzles in the mixing chamber, rarefaction zones are created, and under the influence of the pressure difference, the surrounding air is sucked into the ejector through the inlet nozzle and accelerated.

The positive effect of the application of tangential injection allows the device to work with a large back pressure at the exit of the ejector, compared to a slot ejector.

However, due to the discreteness of the injection system, the velocity field has significant inhomogeneity in the transverse direction across the channel of the mixing chamber. At the same time, the degree of mixing of high-speed and secondary flows decreases. As a result, the ejection coefficient drops.

In general, the total pressure losses due to the mixing of flows in the gas ejector and its linear dimensions depend significantly not only on the pressure drop in the nozzle, the shape of the mixing chamber, the ejection coefficient, but also on its structural layout.

The efficiency of the ejector can be increased by improving the gas-dynamic path.

The idea is to shape the geometry of the supercharging system using multi-nozzle systems.

Moreover, by means of ZO-composition, the directionality in the space of the nozzle system should be made in such a way as to ensure the maximum effective area of interaction of a large number of high-pressure jets flowing out with the secondary flow.

The useful model is based on the task of intensifying the process of mass exchange of gases of primary and secondary flows.

The task is solved by the fact that the gas ejector, consisting of an inlet nozzle and a diffuser body, in which an annular insert is placed, which has an annular pressure chamber with nozzle holes directed along the wall of the internal channel, according to the useful model, contains a nozzle module, which are placed inside the ejector tract and connected to the annular chamber by a pylon-pipe and directed at an angle to the axis of the ejector in the area between the nozzles of the annular insert.

The drawing explains the essence of a useful model.

The design scheme of the device is shown in the drawing, where: 1 - the ejected stream; 2 - inlet nozzle of suction gas; C - nozzle module; 4 - pylon pipe; 5 - compressed gas flow; b - fitting; 7 - ring pressure chamber; 8 - ring insert; 9 - nozzle in the ring chamber; 10 - module nozzle; 11 - a package of wall jets flowing from the nozzles of the annular chamber; 12 - a package of free jets flowing from the nozzles of the module; 13 - body - diffuser; 14 - gas flow at the exit from the ejector.

The principle of action of the ejector is as follows. The compressed air 5 through the fitting 6 enters the annular chamber 7, from where it is blown through the nozzle 9 in the wall of the annular insert 8 in the form of a packet of longitudinal wall jets 11 at supersonic speed into the channel in the direction of the outlet section of the body - diffuser 13. At the same time, a packet of central high-speed jets 12 is added , which flow from the nozzles 10 of module 3. The discharge zone, which is formed by the outflow of high-speed jet packets inside the ejector, sucks the secondary flow of gas 1, which is ejected, through the inlet nozzle 2.

The peculiarity of the work of the proposed technical solution is that the placement of an additional nozzle module inside the tract allows for denser packing in the space of high-speed jet packages. We have two packages of mutually penetrating longitudinal jets, namely the combs of one group enter the space (gaps) between the jets of the second group.

Dispersed in the space of the gas-dynamic tract, the nozzles for blowing the high-speed primary flow significantly change the pattern of gas flow inside the device. At the same time, the intensity of mass exchange between the primary and secondary gas flows inside the ejector increases.

An additional package of central nozzles allows to increase the pressure at the exit of the ejector / the degree of vacuum in the inlet nozzle. A denser arrangement of the package of high-speed jets ensures an increase in the ejection coefficient and an increase in the level of the ejector's consumption parameters.

As a result, the characteristics of the device as a whole improve, while the overall parameters of the device do not change or even decrease.

Improving the characteristics of the ejector expands the scope of their use, will allow the creation of functionally new units and devices. Possible application in the development of new technological lines (including transport, vacuum) in mechanical engineering and the food industry.

Sources of information: 1. Khristianovych S.A., Halperin V.G., Millionshchikov M.D., Simonov L.A. Applied gas dynamics. Part 1, 2 - M.: TSAGY, 1948. 2. Arkadov Yu.K. The optimal gas burner with a diffuser. - A student of TsAGA's notes. 1980, v. 11, Mo. 2. 3. Yanov A.P., Gagauz F.G., Drebnitsa A.V., Pereverzov V.V. A torch for ventilating mining wastes. - Auth. certificate Mo 259018, Bul. image and goods Znakov, 1970, Mo 2. 4. Korobov V.Y., Zagumennyi Y.V., Paramonov Yu.A. It flows in a jet system with a semi-confined high-speed jet. - Applied Hydromechanics, Institute of Hydromechanics of the National Academy of Sciences

of Ukraine, Kyiv, 2007, vol. 8, Mo. 1, p. 36-44. feast//azrase approx. home tsa/byzigteat/napa!|ie/123456789/4692/04-Kogobom, rag?zednepse-1 5. pe Mas. - Ehaig Sogrogaiiop SaiaIod 22. pyrz/Lymly.ehaii-sot/Lipe-mas.piti - the closest analogue.

Claims (1)

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