RU143832U1 - JET PUMP - Google Patents

Abstract

A jet pump comprising a nozzle body, a mixing chamber, a diffuser and a wear-resistant flow insert located in the nozzle body, characterized in that the wear-resistant flow insert is detachable and consists of at least two parts contacting each other along the plane of the connector, this plane of the connector passes through the longitudinal axis of the wear-resistant flow insert.

Description

The utility model relates to pump engineering, in particular to jet pumps, and can be used in the oil, gas and other industries for the extraction of liquids, gases and gas-liquid mixtures from wells, including can be used to create technologies and equipment for collection systems and the preparation of oil and gas, and for water-gas effects on oil reservoirs.

Known jet pump containing a nozzle body, a mixing chamber, a diffuser and a wear-resistant flow insert located in the nozzle body (Utility Model Certificate No. 321, F04F 05/10. Jet pump. Published: 04/16/1995).

A disadvantage of the known jet pump is the relatively low manufacturability of the manufacture of the nozzle and, in this regard, the relatively narrow scope of such jet pumps.

The task to be solved by the present technical solution is to increase manufacturability and expand the scope of jet pumps, especially in oil production.

The technical result is the creation of a more technological design of the nozzle and the flow part of the jet pump, which will widely use the well-known effective technologies for hardening parts, including hardening technology for the outer surfaces of parts. At the same time, costs are reduced at the production stage and at the stage of operation of jet pumps.

The specified technical result is achieved in that the jet pump contains a nozzle body, a mixing chamber, a diffuser and a wear-resistant flow insert located in the nozzle body. The wear-resistant flow insert is made detachable and consists of at least two parts in contact with each other along the plane of the connector. In this case, the plane of the connector passes through the longitudinal axis of the wear-resistant flow insert.

The jet pump may be implemented when the mixing chamber is detachable and consists of at least two parts in contact with each other along the plane of the connector.

In figures 1-2 for the convenience of describing the claimed technical solution presents additional graphic materials.

The figure 1 presents a diagram of a jet pump, with a longitudinal section.

Figure 2 shows an isometric view of the nozzle body and a wear-resistant flow insert, which is detachable and consists of two parts in contact with each other along the plane of the connector. For the convenience of design description, the two parts of the wear-resistant flow insert are offset along the longitudinal axis and are apart from each other.

The jet pump, according to figures 1-2, contains a nozzle body 1, a mixing chamber 2, a diffuser 3 and a wear-resistant flow insert 4 located in the nozzle housing 1. The wear-resistant flow insert 4 is detachable and consists of at least two parts 5 and 6 in contact with each other along the plane of the connector 7. In this case, the plane of the connector 7 passes through the longitudinal axis 8 of the wear-resistant flow insert 4.

The mixing chamber 2 and the diffuser 3 are made in the housing 9 of the jet pump. The inlet pipe 10 of FIG. 1 fixes a wear-resistant flow insert 4 located in the housing of the nozzle 1. The input channel 11 for the pumped medium communicates with the mixing chamber 2, and then through the diffuser 3 communicates with the output channel 12.

The jet pump can also be implemented when the mixing chamber 2 is detachable and consists of at least two parts in contact with each other along the plane of the connector (not shown in the figures).

The jet pump operates as follows.

The pumped medium is supplied to the flow part of the jet pump through the inlet 11. The working fluid is fed through the inlet 10 to a wear-resistant flow insert 4 located in the nozzle body 1. In the tapering part of the wear-resistant flow insert 4, the potential energy is converted into kinetic energy and a jet of working fluid is formed directed into the mixing chamber 2. Since the mixing chamber 2 is filled with the pumped medium (it can be a liquid, gas or gas-liquid mixture), at the boundary of the working fluid stream A boundary layer is formed where mixing of the working fluid with the pumped medium takes place. Thus, due to mixing, a force effect is applied to the pumped medium, and part of the energy is transferred from the working fluid to the pumped medium. Energy transfer is carried out with the participation of friction forces, for this reason jet pumps were assigned to the group of dynamic pumps, friction pumps. The pumped medium is supplied to the jet of working fluid passing through the inlet 11. The mixed stream then passes through the mixing chamber 2. The jet pump contains a diffuser 3 connected to the outlet of the mixing chamber 2, the flow velocity in the diffuser 3 decreases, and kinetic energy is converted into potential energy , which is accompanied by an increase in the static component of pressure. From the diffuser 3, the mixture of the working fluid and the pumped medium enters the outlet channel 12.

The proposed technical solution allows the use of known effective technologies for hardening parts (for example, technology for surfacing wear-resistant materials), including technology for hardening the outer surfaces of parts, since the wear-resistant flow insert 4 is detachable and consists of at least two parts 5 and 6, contacting each other along the plane of the connector 7. In this case, the plane of the connector 7 passes through the longitudinal axis 8 of the wear-resistant flow insert 4. Using a collapsible design appears it is possible to harden the inner surface of the wear-resistant flow insert 4 by applying hardening technology calculated for the outer surfaces of the parts, this goal is achieved by separately processing parts 5 and 6. Thus, the complex technological problem of processing and quality control of internal surfaces and channels of small diameter is solved, which is typical for the production of jet pumps. Thus, the task of improving manufacturability and expanding the scope of jet pumps, including in oil production, is being solved. At the same time, costs are reduced at the production stage and at the stage of operation of jet pumps.

Claims (1)

A jet pump comprising a nozzle body, a mixing chamber, a diffuser and a wear-resistant flow insert located in the nozzle body, characterized in that the wear-resistant flow insert is made detachable and consists of at least two parts in contact with each other along the plane of the connector, this plane of the connector passes through the longitudinal axis of the wear-resistant flow insert.