RU2113629C1 - Liquid-gas jet device - Google Patents

Abstract

FIELD: pumping out steam and gas medium. SUBSTANCE: active liquid supply nozzle has central and peripheral annular barrels carrying active liquid medium; total outlet sectional area of this nozzle is found from equation

, where S is total outlet sectional area of nozzle; S_c is outlet sectional area of central barrel; S_mch is minimal sectional area of mixing chamber. EFFECT: improved reliability of jet device. 3 cl, 2 dwg

Description

 The invention relates to inkjet technology, mainly to vacuum jet devices for pumping out a gas-vapor medium in various technological cycles.

 Known vacuum jet apparatus containing a nozzle for supplying an active vapor medium, a mixing chamber and a diffuser [1]. However, this inkjet apparatus has a low efficiency and requires large energy expenditures to create an active vapor medium.

 Closest to the described is a liquid-gas jet apparatus containing a nozzle for supplying an active liquid medium and a mixing chamber [2].

 This inkjet apparatus creates a vacuum in the pumped out object due to the energy of the flow of the active liquid medium, which allows you to create a fairly compact stand-alone installation for pumping various combined-cycle media. However, in this jet apparatus it is difficult, and in some cases it is impossible to achieve stable operation when performing the apparatus for pumping large flows of the vapor-gas phase, which is due to the fact that the influence of the scale factor practically negates the features of the formation of the active medium flow in the nozzle embedded in this apparatus.

 The objective of the invention is to increase the reliability of the inkjet apparatus due to the formation of a more stable flow of the active liquid medium and reduce energy loss of the flow of the active medium in the interaction of the active (ejection) and passive (pumped out) media.

где
S - суммарная площадь выходного сечения сопла;
S_ц - площадь выходного сечения центрального ствола сопла;
S_кс - площадь минимального сечения камеры смешения.The problem is solved due to the fact that in the liquid-gas jet apparatus containing the nozzle for supplying the active liquid medium and the mixing chamber, the nozzle for supplying the active liquid medium is made with central and peripheral annular shafts for supplying the active liquid medium, and the total area of the exit section of the nozzle for supplying the active liquid environment is determined from the expression:

Where
S is the total area of the outlet section of the nozzle;
S _c - the area of the output section of the Central barrel of the nozzle;
S _cc is the minimum cross-sectional area of the mixing chamber.

 The output section of the central barrel may lie in the plane of the cross-section of the peripheral barrel, or the output section of the peripheral barrel may be shifted relative to the output section of the central barrel in the opposite direction to the flow of the active medium.

As the studies showed, the implementation of the nozzle for supplying the active liquid medium in the form of two shafts - the central and circular peripheral - allows more efficient use of the energy of the active liquid medium, namely, to reduce energy losses at the moment of contact of the active (ejection) and passive (pumped out) media. The flow of the active medium, flowing out of the peripheral trunk, provides the primary contact of the active and passive media, increasing the kinetic energy of the latter, which in turn reduces the impact loss during the transfer of kinetic energy from the active medium of the central trunk. In addition, the formation of two flows of the active medium made it possible to significantly increase the peripheral unstable region of the active medium flow, which helped create a zone of a gradual increase in the kinetic energy of the passive medium. This is especially important when the vapor-gas medium is pumped out, which includes vapor phase condensate droplets that are quite large compared with gas molecules. In this regard, the ratio of the areas of the central and peripheral nozzle shafts and the relationship between their area and the minimum cross-sectional area of the mixing chamber are essential. The studies showed that the ratio of these cross-sectional areas, found and presented in the form of the calculation dependence indicated above, made it possible to find their optimal ratio for various flow characteristics of the liquid-gas jet apparatus, while it is advisable that the ratio S _cc / S _{c be} in the range from 10 to 78, and the ratio of S _x / S would lie in the range from 2.4 to 7.93.

 In some cases, the spatial position of the output sections of the central and peripheral shafts relative to each other can also have a significant effect. The most common case is when the output sections of the central and peripheral trunks lie in the same plane of the cross section. However, in some cases, in particular, when the pumped-out medium contains a large number of easily condensable vapors, many drops are contained in the gas-vapor passive medium. In this case, it is advisable to shift the output section of the peripheral barrel in the direction against the flow of the active medium. In this case, it is possible, as it were, to extend the contact time of the active and passive media and, due to this, more smoothly disperse the passive medium with less impact losses in the collision of the active and passive media.

 Thus, the implementation of a liquid-gas jet apparatus in the manner described above made it possible to achieve the stated technical task - to increase the reliability of the jet apparatus during the pumping of various combined-cycle media.

 In FIG. 1 is a schematic representation of the described liquid-gas jet apparatus; in FIG. 2 shows an embodiment of a nozzle for supplying an active liquid medium with a peripheral annular shaft shifted against the flow of the active medium.

где
S - площадь выходного сечения центрального ствола сопла;
S_кс - площадь минимального сечения камеры смешения.The liquid-gas jet apparatus comprises a mixing chamber 1 and an active liquid medium supply nozzle 2 made with a central barrel 3 and a peripheral annular barrel 4. The total area S of the output section of the active nozzle is determined from the expression:

Where
S is the area of the output section of the Central barrel of the nozzle;
S _cc is the minimum cross-sectional area of the mixing chamber.

Жидкостно-газовый струйный аппарат работает следующим образом.The output section of the Central barrel 3 may lie in the plane of the cross section of the output section of the peripheral annular barrel 4 or the output section of the peripheral barrel 4 may be 1 shifted relative to the output section of the Central barrel 3 against the flow of active medium by a distance l, which is selected based on the expression

A liquid-gas jet apparatus operates as follows.

 The active liquid medium, flowing out from the peripheral barrel 4 and the central barrel 3, carries into the mixing chamber 1 a gaseous or vapor-gas passive (pumped out) medium. As a result of mixing the active and passive media, a gas-liquid flow is formed with the passive medium transferring part of the kinetic energy of the active medium. From the mixing chamber 1, the gas-liquid mixture is supplied for its intended purpose, for example, to a separator (not shown), where the liquid active medium is separated from the pumped gas compressed by it.

 The above-described liquid-gas jet apparatus can be widely used in many industries, especially in petrochemicals in the vacuum processing of petroleum feedstocks in distillation vacuum columns.

Claims (3)

1. A liquid-gas jet apparatus comprising a nozzle for supplying an active liquid medium and a mixing chamber, characterized in that the nozzle for supplying an active liquid medium is made with a central and peripheral annular barrel for supplying an active liquid medium, and the total exit section area of the nozzle for supplying an active liquid medium is determined from expression

where S is the total area of the outlet section of the nozzle;
S _c - the area of the output section of the Central barrel of the nozzle;
S _cc is the minimum cross-sectional area of the mixing chamber.  2. The inkjet apparatus according to claim 1, characterized in that the output section of the central barrel lies in the plane of the cross section of the output section of the peripheral barrel.  3. The inkjet apparatus according to claim 1, characterized in that the output section of the peripheral barrel is shifted relative to the output section of the central barrel in the direction against the flow of the active medium.

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