RU2621924C9 - Gas ejector - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: ejector is intended for de-gassing. Ejector provides the suction chamber, mixing chamber with diffuser and nozzle located coaxially. The ejector is multichannel. The multi-nozzle chamber is rigidly fixed in a stationary housing. The multichannel housing is made of thermoplastic or composite materials, or metals with a density of not more than 5 g/cm. Each channel of a multichannel casing is a suction chamber, mixing chamber and the exhaust diffuser. Each nozzle has its own channel. Head-capacity curves of the ejector are provided by geometrical relationships and ranges of ejector sizes.EFFECT: increased ejection coefficient, reduced mass and ease of the ejector operation.2 cl, 5 dwg

Description

The invention relates to inkjet technology, and in particular to gas ejectors with supersonic nozzles and tapering mixing chambers, can be used in aviation and industrial industry for pumping gases, dust-air mixtures in dustproof devices, as well as in heating, ventilation and air conditioning systems on helicopters.

Various ejectors are known, which are a coaxially mounted active gas nozzle and a rigidly fixed cylindrical mixing chamber with an exhaust conical diffuser (Sokolov E.Ya., Singer N.M. Inkjet devices, 3rd ed., Revised. - M.: Energoatomizdat, 1989 .; Collection of works on the study of supersonic gas ejectors, TsAGI 1961).

Closest to the claimed technical solution is a gas ejector containing a tapering mixing chamber, a throat, a subsonic diffuser and a central supersonic nozzle. Small-sized vortex generators made in the form of tabs are evenly placed on the outlet edge of the nozzle (patent RU 2341691, priority dated January 9, 2007 IPC F04F 5/18, F04F 5/44).

The disadvantages of the ejectors considered in these publications are: non-optimal configurations of the active gas nozzle, receiving chamber, mixing chamber and exhaust diffuser, which does not fully achieve the necessary ratio of the ejection coefficient and rarefaction at the entrance to the receiving chamber. Also, disadvantages include large dimensions (due to the need to use a long mixing chamber, of the order of 4 ... 8 calibers) and the absence of light, quick-disconnect or opening ejector designs.

The objectives of the proposed technical solution is to increase the ejection coefficient k≥7, reduce the mass and overall size in order to optimize the layout of the product, as well as the design in quick release design.

The problem is solved due to the fact that a gas ejector containing a receiving chamber, a mixing chamber with a diffuser and a coaxially located nozzle, according to the claimed invention, the ejector is made multi-channel in the form of a multi-nozzle camera and a multi-channel body made of thermoplastic or composite materials rigidly fixed in a stationary housing or metals with a density of not more than 5 g / cm ^3, wherein each channel is a receiving chamber, the mixing chamber and the exhaust diffuser, wherein each con y corresponds to a channel, and consumables-pressure characteristics of the ejector provided with the following geometrical relationships and ranges of sizes:

n≥2

l ₁ / d = 0.1 ... 1.5,

l ₂ / d = 0.7 ... 4,

α ₁ = 10 ... 30 °,

D _equiv / d = 7.5 ... 9,

L ₁ / D _equiv = 0.75 ... 2.5,

L ₂ / D _equiv = 1.5 ... 6,

L ₃ / D _equiv = 3.5 ... 8,

α ₄ = 10 ... 30 °,

where n is the number of nozzles in the multi-nozzle chamber,

d is the inner diameter of the nozzle,

l ₁ - the length of the nozzle passage,

l ₂ is the length of the nozzle opening section,

α ₁ - the angle of the nozzle,

D _equiv - equivalent diameter of the mixing chamber,

L ₁ - the length of the plot from the nozzle exit to the entrance to the mixing chamber,

L ₂ - the length of the mixing chamber,

L ₃ - the length of the exhaust diffuser,

α ₄ - the angle of the exhaust diffuser.

Moreover, the multi-channel housing is made with the possibility of opening.

The proposed multi-nozzle design allows to reduce the size and mass of the ejector with an increase in the ejection coefficient to k≥7, while the ease of operation is achieved thanks to the locking-opening mechanism while maintaining the alignment of the nozzle chamber and the multi-channel housing.

The claimed invention is illustrated by drawings:

FIG. 1 is a general view of an ejector with a multi-nozzle chamber in an ajar state;

FIG. 2 is a sectional view of a spring lock;

FIG. 3 - general view of the ejector in the closed state;

FIG. 4 - the main geometric dimensions of the nozzle;

FIG. 5 - the main geometric dimensions of the ejector assembly.

The gas ejector (Fig. 1) consists of a stationary housing 1 and an opening multi-channel housing 2.

A multi-nozzle chamber 3 with an active gas supply flange 4 and nozzles 5 in an amount of more than two, for example seven, is fixed in the stationary housing 1. The locking-opening mechanism (Fig. 2) is made in the form of loops 6 on the stationary housing 1 of the spring locks 7 and mating elements 8 under the spring locks 7 on the multichannel housing, while the gasket 9 is laid along the contour of the stationary housing 1 (Fig. 1), ensuring tightness of the fit of stationary 1 and multi-channel 2 buildings.

The opening multi-channel housing 2 (Fig. 3) of the ejector consists of receiving chambers 10 and mixing chambers 11 with exhaust diffusers 12 while each channel of the housing 2 has its own nozzle 5.

The multi-channel housing 2 of the ejector is made of thermoplastic materials, with the following main characteristics:

- The elastic modulus (E) in the range of 4000 ... 7000 MPa (preferably 4000 ... 5000 MPa);

- Elongation at break of 3 ... 6% (preferably 4 ... 5%);

- Operating temperature -60 ... + 130C °.

The multi-channel housing 2 can also be made of composite materials or of metals with a density of not more than 5 g / cm ³ .

In FIG. 4 shows a nozzle indicating the following parameters and ratios:

nozzle opening angle α ₁ = 10 ... 30 ° (preferably α ₁ = 20 ... 23 °),

the narrowing angle in front of the nozzle α ₂ = 30 ... 60 ° (preferably α ₂ = 40 ... 43 °),

l ₁ / d = 0.1 ... 1.5 (preferably l ₁ / d = 0.35 ... 0.4),

l ₂ / d = 0.7 ... 4 (preferably l ₂ / d = 0.7 ... 0.9),

where d is the inner diameter of the nozzle,

l ₁ - the length of the nozzle passage,

l ₂ - the length of the nozzle disclosure.

In FIG. 5 shows the ejector assembly with the following parameters and ratios:

the narrowing angle of the receiving chamber α ₃ = 30 ... 60 ° (preferably α ₃ = 43 ... 48 °);

the opening angle of the exhaust diffuser α ₄ = 10 ... 30 ° (preferably α ₄ = 20 ... 23 °);

D _equiv / d = 7.5 ... 9 (preferably D _equiv / d = 8 ... 8.5);

L ₁ / D _equiv = 0.75 ... 2.5 (preferably L ₁ / D _equiv = 1.2 ... 1.7);

L ₂ / D _equiv = 1.5 ... 6 (preferably L ₂ / D _equiv = 1.5 ... 1.9);

L ₃ / D _EQ = 3.5 ... 8 (preferably L ₃ / D _EQ = 4 ... 5),

where D _EQ is the equivalent diameter of the mixing chamber,

L ₁ - the length of the plot from the nozzle exit to the entrance to the mixing chamber,

L ₂ - the length of the mixing chamber,

L ₃ - the length of the exhaust diffuser.

The work of the gas ejector is as follows.

In the nozzle chamber 3 in the stationary housing 1 through the flange 4 serves the active (ejection) gas (direction A) (Fig. 4) with the following parameters: G _a = 0.11 kg / s; P _a = 7.4 ata; t = 280 ° C,

where G _a is the flow rate of the active gas,

P _a is the pressure of the active gas,

t is the temperature of the active gas.

The active gas, distributed evenly throughout the multi-nozzle chamber 3, exits nozzles 5 at a speed of about 800 m / s and enters the receiving chambers 10, each corresponding to its own nozzle 5 (stream B, FIG. 5).

Entering the receiving chambers 10 (flow In FIG. 5), and then into the mixing chambers 11, the active gas transfers part of its kinetic energy to the passive gas at rest, resulting in gas mixing and velocity equalization, as a result of which the passive gas acquires acceleration and it sucks from the outside into the receiving chambers 10, thus creating a vacuum at the entrance to the ejector (stream B). From the mixing chambers 11, the gas flow enters the exhaust diffusers 12 (direction C, Fig. 5), where there is a further increase in pressure, and at the inlet of the receiving chambers 10, respectively, a further decrease in pressure or an increase in vacuum.

The passive air flow rate for this design is 0.86 kg / s with a network resistance at the inlet to the receiving chambers 10 equal to zero and 0.78 kg / s with a network resistance at the entrance to the receiving chambers of the ejector equal to 300 mm water column, which corresponds to an ejection coefficient of 7.1 ... 7.8.

The ejector is opened as follows - they are pulled by the rings of the spring locks 7 in the D direction (Fig. 2, Fig. 3), the mating elements 8 located on the multi-channel housing 2 will disengage from the spring locks 7 and the opening multi-channel housing 2 on the hinges 6 will open way down.

The ejector is closed in the reverse order - the multi-channel housing 2 is lifted and pressed to the stationary housing 1, the spring locks 7 are retracted by the rings in the D direction (Fig. 2, Fig. 3), the multi-channel housing 2 is pressed more tightly against the gasket 9, the spring locks 7 are released and engage with the mating elements 8 of the spring locks 7, thus the multi-channel housing 2 is fixed in the closed position.

Claims (21)

1. A gas ejector containing a receiving chamber, a mixing chamber with a diffuser and a coaxially located nozzle, characterized in that the ejector is made multi-channel in the form of a multi-nozzle chamber and a multi-channel body rigidly fixed in a stationary housing made of thermoplastic or composite materials, or metals with a density not more than 5 g / cm ^3, wherein each channel is a receiving chamber, the mixing chamber and the exhaust diffuser, wherein each nozzle has its own channel, and the consumable-pressure characteristic and the ejector are provided with the following geometrical relationships and ranges of sizes: n≥2 l ₁ / d = 0.1 ... 1.5, l ₂ / d = 0.7 ... 4, α ₁ = 10 ... 30 ^o , D _equiv / d = 7.5 ... 9, L ₁ / D _equiv = 0.75 ... 2.5, L ₂ / D _equiv = 1.5 ... 6, L ₃ / D _equiv = 3.5 ... 8, α ₄ = 10 ... 30 °, where n is the number of nozzles in the multi-nozzle chamber, d is the inner diameter of the nozzle, l ₁ - the length of the orifice of the nozzle, l ₂ is the length of the nozzle opening section, α ₁ - the angle of the nozzle, D _equiv - equivalent diameter of the mixing chamber, L ₁ - the length of the plot from the nozzle exit to the entrance to the mixing chamber, L ₂ - the length of the mixing chamber, L ₃ - the length of the exhaust diffuser, α ₄ - the angle of the exhaust diffuser. 2. The gas ejector according to claim 1, characterized in that the multi-channel housing is made with the possibility of opening.

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