SU1132074A1 - Vibration pump - Google Patents

Abstract

1. VIBRATION PUMP containing a vibration drive connected to a transport pipeline, and placed in the last working device, characterized in that, in order to increase efficiency by increasing the energy exchange between the working body and the transported liquid, the working body is made in the form of blades attached to the internal surface of the transport pipeline with a slope from the entrance to the exit. 2. A pump according to claim 1, characterized in that each JfcnaTKa in a cross section is rotated about an axis with respect to the previous one. (L oo 1C about 42

Description

The invention relates to pump engineering and can be used in pumps for oil production.

A vibration type pump is known, for example, a two-mass vibration pump 1.

The disadvantages of this pump are the design complexity, the presence of rubbing pairs, the large overall dimensions.

Known vibrating pump containing vibrogivod connected to the transport pipeline, and placed in the last working body, made in the form of nozzles 2.

A disadvantage of the known vibration pump is the presence of a working body in the form of nozzles, which significantly reduces the efficiency of the pump.

The purpose of the invention is to increase the efficiency of the pump by increasing the energy exchange between the working member and the fluid being transported.

This goal is achieved by the fact that in a vibrating pump containing a vibration drive connected to a transport pipeline and a slave organ placed in the latter, the working member is made in the form of blades fixed on the inner surface of the transport pipeline with an inclination from the inlet to the outlet.

In this case, each next blade in cross section is rotated all the axis relative to the previous one.

FIG. 1 shows a diagram of a vibration pump, a longitudinal section; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows an embodiment of a vibration pump with a fairing, longitudinal section; in fig. 4 is a section BB in FIG. 3; in fig. 5 shows a pump with blades rotated relative to each other, longitudinal section; in fig. 6 is a sectional view BB in FIG. five; in fig. 7 — components of the velocities at the inlet to the blades and the exit from them with the circulation character of the flow; in fig. 8 shows the experimental characteristics of the flow rate as a function of the pressure drop through the pipe with the blades in the forward and reverse directions.

Vibrating pump contains a vibration drive 1 connected to the transport pipeline 2, and placed in the last working body, made in the form of blades 3 mounted on the inner surface of the transport pipeline 2 with a slope from inlet to outlet, while

each next blade 3 in cross section is rotated around an axis relative to the previous one, and a fairing 4 is installed in the transport pipeline 2.

The vibration pump works as follows.

Due to the vibratory drive 1 oscillations with a certain frequency, the transport pipeline 2 is driven back and forth. The flow of fluid from the inlet to the outlet in the transport pipeline is due to the interaction. The pressure forces and the inertial forces and the interaction of the blades 3 with the liquid in the pipeline 2, which ensure mainly one-sided conductivity. This is explained by the fact that with relative fluid movement in the forward direction from the inlet to the outlet, the blades 3 are inclined downstream, and therefore the hydraulic resistance is small. With

 the reverse flow of the blade is directed against the flow, which causes its circulation (Fig. 7). In this case, part of the fluid enters the interscapular space with an axial component. C, circulating C0J, then from the interscapular space, the liquid directed by the blades comes out towards the main flow and partially blocks it, with the locking component Cg C0 ctgJB, where J3 is the angle of rotation of the blade. The strengthening of the circulating flow and, thus, an increase in the locking effect can be facilitated by the installation of a fairing 4 along the pipe axis (Fig. 3 and 4) or rotation of the blades around the axis in cross section (Fig. 5 and 6), although this leads to some the complexity of the design.

FIG. Figure 8 shows the dependence of TG (DR) in the form of the energy characteristic of a pipe with inclined vanes installed in it, blown directly and

0 reverse directions, where w - mass air flow; AR - pressure drop. From this it is obvious that the costs in the forward and reverse directions differ significantly (about 10 times).

5 Thus, the implementation of the working body of the vibration pump in the form of blades fixed on the inner surface of the transport pipeline provides preferential conductivity in the forward direction (along the blades) and performs

0 the role of valves with moving parts with a limited service life.

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Claims (2)

1. VIBRATION PUMP containing a vibrodrive connected to the transport pipeline and placed in the last working body, characterized in that, in order to increase efficiency by increasing energy exchange between the working body and the transported liquid, the working body is made in the form of vanes mounted on the inner surface transport pipeline with an inclination from entrance to exit. 2. The pump according to π. 1, characterized in that each / staple in cross section is rotated around an axis relative to the previous one. >