RU2462622C2 - Vibratory pump - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: in housing 1 of vibratory pump there fixed is electromagnet 2 containing magnetic conductor that represents a common part that is made of a set of bands of electrotechnical steel. Coil winding 3 is installed in annular gap between cores. Core 4 of electromagnet 2 is made in the form of a bobbin of band of electrotechnical steel and rigidly attached through hollow stock 5 with two rubber-metal shock absorbers 7 and 9. In shock absorbers 7 and 9 there installed are central threaded sleeves 6 and 8. Hollow stock 5 is rigidly fixed with one end in sleeve 6 of shock absorber 7. The other end of stock 5 is rigidly fixed in sleeve 8 of shock absorber 9. Cover 10 with suction valve 11 installed in it and shock absorber 7 are fixed on housing 1 and form working chamber 12 of the first pump stage. Shock absorber 9 is fixed on the other end of housing 1 through cover 13 in which delivery valve 14 is installed so that working chamber 15 of the second pump stage is formed. Valve 16 which is delivery valve for the first stage of the pump, and which is the suction valve for the second stage of pump, is installed on sleeve 8.

EFFECT: simpler pump design, improved reliability and increased head.

2 cl, 2 dwg

Description

The invention relates to electrical engineering, to the production of submersible pumps with an electromagnetic vibratory drive, and can be used in everyday life for lifting water from wells, wells and other sources.

Known submersible electromagnetic vibration pump (see RU 2154198 C1, 07/09/1999, F04F 7/00). Its magnetic core consists of two cylindrical cores, placed one in the other with an annular gap, between which an electric winding coil is placed, and a third core - a yoke, which is made in the form of a washer from plates of electrical steel and which closes the upper ends of the cylindrical cores. The anchor of the electromagnet is made similar to the yoke. The central core of the magnetic circuit has an axial hole for the passage of the rod, which connects the diaphragm mounted in the lower cover of the housing, an anchor, a shock absorber and a piston. An inlet valve and an outlet pipe are installed in the upper housing cover.

The main advantage of this pump is that the force created by the electromagnet is directly aimed at creating working pressure. Having certain advantages over other analogues, this pump is still not without some drawbacks. In it, the cylindrical cores are placed one in the other and are freely mounted on a yoke, which is made in the form of a washer from plates of electrical steel and serving to close the magnetic circuit. The anchor of the electromagnet is made similar to the yoke. Magnetic fluxes from the cores pass through the yoke and the armature in cross sections, and this leads to magnetic losses. The apparent simplicity of manufacturing individual parts of the cylindrical cores and the yoke violates the integrity of the design of the magnetic circuit, which complicates their rigid mounting with the housing.

A vibration pump is known (see SU 241225 A, 04/01/1964, F04B 43/04). In this pump, an elastic working element of the type of a vibrating fin is fixed on the actuator rod, forming the first stage of the pump with the conical surface of the housing. The second stage is formed by an elastic ring with a conical inner surface, which is mounted on the body and interacting with it by a cone-shaped rigid ring fixed on the rod above the elastic fin. In the specified pump, the second elastic working element is also of the type of a vibrating fin, moreover, of a larger diameter and forming the second stage of the pump with a rigid cone-shaped ring mounted on the rod, the pressure in which should be greater than in the first stage, and this will require additional drive power .

Known vibration pump (see RU 2139453 C1, 10.10.1999, F04F 7/00). In this pump, a service valve is installed in the hollow stem from the back cover side with the formation of a variable volume hydraulic chamber between it and the front cover. The main advantage of this pump is that heat is removed during operation of the pump both from the external surface and from the inside. In the specified pump, the back cover and the elastic suspension with the hollow rod fixed in it, in which the operating valve is installed, forms a chamber with a variable volume. The elastic suspension in this chamber works like a piston, and this is an additional resistance for the force of the electromagnet. Installing a service valve in a hollow stem reduces the bore of the stem, which creates additional flow resistance. It is possible to install a ball valve in a hollow stem, and installing a flat or cylindrical valve will create structural problems.

The objective of the invention is to simplify the design of the pump while increasing its reliability and increasing pressure.

The problem is solved by the fact that in a vibration pump containing a housing, an electromagnetic vibrator placed therein with a magnetic circuit, an electric coil and an armature, which is connected through a hollow rod to a shock absorber, the lower and upper covers, in which the suction and discharge valves are installed, according to the invention, a magnetic circuit of an armored-type electromagnet, consisting of cylindrical cores with outer and inner diameters, between which an annular gap is formed, and a yoke, n from a set of electrical steel tapes as a single part, and the electromagnet anchor, made in the form of a bobbin of electrical steel tape, is rigidly connected through a hollow rod to two rubber-metal shock absorbers, in which central threaded bushings are installed, one of which is mounted on the lower end of the housing and mounted on through the bottom cover with a suction valve installed in it with the formation of the working chamber of the first stage, and the second is mounted on its upper end and secured through the upper cover with installed m in it with a discharge valve and forms a working chamber of the second stage, while the discharge valve of the first stage is installed in the central threaded sleeve of the second rubber-metal shock absorber and at the same time is the suction valve of the second stage of the pump.

In addition, the suction and discharge valves of the pump can be made flat or spherical.

The above technical results are ensured by the fact that the magnetic circuit is made of a set of electrical steel tapes as a single part, and this simplifies the manufacture of an electromagnet. Magnetic fluxes between the armature and the cores of the electromagnet go in the longitudinal direction, which leads to a decrease in magnetic losses. The manufacture of a magnetic circuit as a single part ensures its reliable installation and fastening in the body of an electromagnet. An electromagnet anchor, made in the form of a bobbin of electrical steel tape, is rigidly connected through a hollow rod to two rubber-metal shock absorbers, in which central threaded bushings are installed, one of which is mounted on the lower end of the housing and mounted on it through the lower cover with a suction valve installed in it with the formation of the working chamber of the first stage, and the second is mounted on its upper end and secured through the upper cover with a discharge valve installed in it and forms a working chamber th stage, wherein the first stage discharge valve installed in the central threaded sleeve and the second rubber damper is simultaneously a suction valve of the second pump stage.

Such a pump device allows you to transfer the force created by the electromagnet directly to create working pressure through the upper rubber shock absorber in the second stage of the pump and to provide suction and pressure in the first stage of the pump. The total rigidity of rubber-metal shock absorbers makes it possible to increase the pressure in the first stage of the pump and bring it to the calculated one in the second.

Figure 1 shows a vibration pump with flat valves.

Figure 2 - with spherical valves.

Figure 1 presents the described pump, in the housing 1 of which is installed and fixed an electromagnet 2 containing a magnetic circuit, which is made of a set of tapes of electrical steel as a single part. In the annular gap between the cores, an electric winding coil 3 is installed. An electromagnet 4 anchor made in the form of a bobbin of electrical steel tape, the hollow rod 5 is rigidly fixed at one end in the central thread of the sleeve 6 of the rubber shock absorber 7, and the other end of this rod is rigidly fixed in the central threaded the sleeve 8 of the rubber-metal shock absorber 9. The cover 10, with a flat suction valve 11 installed in it, and the rubber-metal shock absorber 7 are mounted on the housing 1 and form a working chamber 12 of the first stage of the pump. On the same housing through the cover 13, in which a flat discharge valve 14 is installed, a rubber-metal shock absorber 9 is mounted on its other end, which forms the working chamber 15 of the second pump stage.

A flat valve 16 is installed on the central threaded sleeve 8, which is a discharge valve for the first stage of the pump, and a suction valve for the second. Figure 2 presents the pump, on the cover 10 of which a suction spherical valve 17 is installed. A threaded sleeve 18 with a spherical valve 19, which is a discharge valve for the first stage of the pump and a suction for the second, is installed on the rubber shock absorber 9. The discharge ball valve 20 is mounted on the cover 13.

When voltage is applied from an alternating current main to an electromagnet, its anchor, rigidly connected to rubber-metal shock absorbers through a hollow rod, makes harmonic oscillations. At the same time, rubber-metal shock absorbers work like pistons with a frequency equal to the double frequency of the supply current. During the period of oscillation, periodic changes in the volumes of the working chambers of the first and second stages of the pump occur. With an increase in the volume of the working chamber of the first stage, the suction valve is open, and the liquid into which the pump is immersed fills it, while the discharge valve is closed. At the same time, a decrease in the volume of the chamber occurs in the second stage of the pump. Its suction valve is closed, and the liquid displaced by the rubber-metal shock absorber under the influence of direct electromagnetic force, through the discharge valve fills the pressure pipe to which the pump is connected. In the next cycle, everything happens the other way around.

Claims (2)

1. A vibration pump, comprising a housing, an electromagnetic vibrator placed therein with a magnetic circuit, an electric coil and an armature, which is connected through a hollow rod to a shock absorber, a lower and upper cover, in which suction and discharge valves are installed, characterized in that the armored magnetic circuit type, consisting of cylindrical cores with outer and inner diameters, between which an annular gap is formed, and a yoke, is made of a set of electrical steel tapes in a single piece pour, and the anchor of the electromagnet, made in the form of a bobbin of electrical steel tape, is rigidly connected through a hollow rod to two rubber-metal shock absorbers, in which central threaded bushings are installed, one of which is installed on the lower end of the housing and mounted on it through the lower cover with installed in it with a suction valve with the formation of the working chamber of the first stage, and the second is installed on its upper end and secured through the upper cover with a pressure valve installed in it and forms a working chamber at the second stage, while the discharge valve of the first stage is installed in the central threaded sleeve of the second rubber-metal shock absorber, and which at the same time is the suction valve of the second stage of the pump. 2. The vibration pump according to claim 1, characterized in that the suction and discharge valves of the pump are made flat or spherical.

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