RU70325U1 - VIBRATION PUMP (OPTIONS) - Google Patents

Abstract

The utility model relates to mechanical engineering, namely to vibration pumps with an electromagnetic drive, designed to lift water from wells, wells and other sources. The technical result consists in the fact that by changing the design and introducing a new unit, a reduction in the path of the fluid in the outlet channel and a decrease in its resistance to movement are achieved, which increases the main operational characteristics of the pump - pressure and productivity. In the first embodiment of the vibration pump, comprising an upper housing with a hydraulic chamber, which has inlets and a central outlet, an elastic valve and an elastic working element associated with an electric actuator located in the lower housing, a separator having a cylindrical shape is installed inside the hydraulic chamber, in the lower parts of which a saddle is made for interacting with an elastic working body, and inlet channels and an outlet channel formed by through opposing channels are formed in the separator body channels connected in the center to a common channel in the form of a pipe that is adjacent to the outlet pipe of the hydraulic chamber, and the inlet channels are located on the sides of the outlet channel, in addition, an elastic valve in which the central hole is made is installed between the separator and the outlet pipe of the hydraulic chamber and the inlets are arranged in a circle around the outlet of the hydraulic chamber. The oncoming channels form a right angle with the common channel or are placed at an angle to each other, and at the junction, the surface of the oncoming channels forms a flow guide made in the form of curved surfaces. The separator is installed in the housing through gaskets. The second option differs from the first in the form of the separator and in the presence of groups of inlet openings symmetrically located with respect to the pump axis, which are overlapped by two elastic valves located between the inlet openings and the inlet channels of the separator. 2 n.p. f-ly, 14 ill.

Description

The utility model relates to mechanical engineering, namely to vibration pumps with an electromagnetic drive, designed to lift water from wells, wells and other sources.

A known design of a vibration pump with an asymmetric arrangement of the exhaust pipe in relation to the working body ("Household vibrating electric pump BV-0.12-40-U5" Malyatko-M ", Operation Manual IBShD 062.823001-12-23 RE"). This arrangement of the exhaust pipe during pump operation leads to vibrations on one side of the pump, which impairs its technical characteristics and affects the reliability of its operation.

A known design of a vibration pump with a lower water intake, in which the outlet channel is located in the yoke body and is made in the form of two symmetrically arranged channels, structurally through a fitting connected centrally to one outlet channel (Household vibration pump BV-0.2-40-U5 TU -U22856653.001-2000 "Operation Manual").

As a prototype, a vibration pump with an upper water intake is selected, which contains an intake housing (upper housing) located in the upper part and a yoke housing (lower housing) in the lower one, the intake housing containing two symmetrically located channels connected in the center to one exhaust channel, made in one piece with it and inlet valves located in the upper part of the intake housing (declaration of patent of Ukraine for utility model No. 1392, published on September 16, 2002).

In the pump described above, the fluid flows in the exhaust channel go a long way with a sharp change in direction. This configuration of the outlet channel leads to the occurrence of standing and reflected waves in the fluid, which reduces the speed and amount of fluid that flows out per unit time, resulting in lower pump performance - pressure and capacity.

In addition, due to the fact that symmetrical channels are located on both sides of the housing, the pump has a large diameter.

These disadvantages are eliminated in the proposed design of the vibration pump.

The objective of the claimed utility model is to create a vibration pump in which, by changing the design and introducing a new unit, a reduction in the path of the fluid in the outlet channel and a decrease in its resistance to movement are achieved, which increases the main operational characteristics of the pump - pressure and performance.

The above technical result is achieved in that in a vibration pump comprising an upper housing with a hydraulic chamber, which has inlets and a central outlet, an elastic valve and an elastic working member associated with an electric actuator located in the lower housing, according to the first embodiment of the utility model inside the hydraulic a separator having a cylindrical shape is installed in the chamber, in the lower part of which a saddle is made for interaction with an elastic working body, moreover, in the body the separator The inlet channels and the outlet channel are formed, formed by through counter channels, connected in the center to a common channel in the form of a pipe that adjoins the outlet pipe of the hydraulic chamber, and the inlet channels are located on the sides of the outlet channel, in addition, an elastic valve in which the central an opening is installed between the separator and the outlet of the hydraulic chamber, and the inlets are arranged in a circle around the outlet of the hydraulic chamber.

In a vibrating pump, the separator outlet duct is formed by at least two oncoming ducts. The oncoming channels form a right angle with the common channel or are placed at an angle to each other. At the junction, the surface of the oncoming channels forms a flow guide made in the form of curved surfaces.

The separator is installed in the housing through gaskets.

In the proposed embodiment, due to the new configuration of the exhaust channel, a reduction in the dimensions of the pump in diameter is achieved, which is an additional technical result.

The essence of the first embodiment of the utility model is illustrated by drawings 1-8, where in Fig.1 is a General view of a vibration pump, a longitudinal section; figure 2 - vibration pump, top view; figure 3, figure 7 is a separator with different forms of exhaust channels; figure 4, figure 8 - separators, top view; figure 5 - the hydraulic part of the pump at the stage of the stroke; figure 6 is the same in the reverse stage.

The vibration pump comprises an upper housing 1, in which a hydraulic chamber 2 is placed, and a lower housing 3, in which an electromagnetic drive with an armature 4 is mounted, connected to an elastic working body 5. In the center of the upper housing 1, an outlet pipe 6 is made, around which inlet openings are located 7.

In the hydraulic chamber 2 there is a separator 8 having a cylindrical shape, in the body of which inlet channels 9 and an outlet channel are formed, formed by two through counter channels 10 connected in the center to a common outlet channel in the form of a pipe 11, which is adjacent to the discharge pipe 6

hydraulic chamber. At the junction, the surface of the oncoming channels forms a flow guide 12, made in the form of curved surfaces.

A saddle 13 is made in the lower part of the separator for interaction with an elastic working body 5.

On the pipe 11 of the outlet channel of the separator planted elastic valve 15, which has a Central hole. The separator is installed in the upper case through the sealing gaskets 16 and 17.

Thus, the separator 8 through the valve combines the inlet openings, inlet channels with the hydraulic chamber, and through the elastic working body - the outlet channel with the outlet pipe of the hydraulic chamber. The separator is connected to the upper case without the use of fasteners.

The vibration pump operates as follows.

The elastic working body 5 divides the hydraulic chamber into two parts: a low-pressure chamber (LPC) and a high-pressure chamber (HPC). In the initial state, the pressure in both chambers is equal.

Working stroke (figure 5). The working body 5 with a sharp downward movement with its elastic petal is firmly pressed against the separator saddle 13, acquiring the shape of a saucer, increasing the volume of the low pressure switch and reducing the volume of the high pressure switch. As a result, a low pressure occurs in the low pressure valve, which leads to the opening of the elastic valve 15 due to the pressure difference outside the pump and in the low pressure valve. Water through the inlet holes 7 and the inlet channels 9 enters the LPC.

The pressure in the HPC increases due to the convexity of the elastic working body 5 and the excess water moves to the outlet channels 10, 11 and the pipe 6.

Reverse stroke (Fig.6). During the reverse stroke, the working body moves upward, while the volume of the low pressure switch decreases, and the high pressure switch increases. The elastic working body opens the KND and the pressure in the KND and KVD are equalized. The increase in pressure in the low pressure valve leads to the closing of the valve 15 inlet 7.

The pressure in the hydraulic chamber is almost equal to the pressure of the liquid column in the outlet channel.

Thus, during the operation of the vibration pump, the liquid through the inlet openings 7 and inlet channels 9 enters the low pressure switch, and then to the high-pressure valve, from where, through the short branches of the exhaust channels 10 and 11, to the exhaust pipe 6.

The presence of two short oncoming channels with a guide, which reduces the resistance of oncoming liquid flows in the exhaust channel, significantly reduces losses arising from the wave motion of the liquid, which as a result leads to an increase in the pressure of the water at the outlet and the pump performance, compared to the prototype, which has a similar power.

In addition, assembling a hydraulic chamber without fasteners increases pump reliability.

The proposed technical solution according to option 1 can significantly reduce the diameter of the pump, which allows it to be used in narrow wells, as well as increase reliability while maintaining the pressure and consumer power compared to analogues with an external diameter of up to 100 mm.

The above technical result is also achieved by the fact that in a vibration pump containing an upper housing with a hydraulic chamber, which has a central outlet pipe, groups of inlet openings located on its sides, elastic valves and an elastic working body associated with an electric drive located in the lower housing , according to the second variant of the utility model, a separator is installed inside the hydraulic chamber, in the lower part of which a saddle is made for interaction with an elastic working body, with in the separator body, inlet channels and an outlet channel are formed, formed by through oncoming channels arranged at an angle to each other and connected in the center to a common channel in the form of a pipe that is adjacent to the outlet pipe of the hydraulic chamber, the inlet channels are located on the sides of the outlet channel, and elastic valves are installed between the inlets and the inlets of the separator.

As in the first embodiment, the outlet channel of the separator is formed by at least two oncoming channels, and at the junction, the surface of the oncoming channels forms a flow guide made in the form of curved surfaces. The separator is installed in the housing through gaskets.

The essence of the second embodiment of the utility model is illustrated by drawings 9-14, where Fig.9 is a General view of a vibration pump, a longitudinal section; figure 10 - vibration pump, top view; figure 11 is a separator; Fig.12 is a separator, top view; on Fig - the hydraulic part of the pump in the stage of the stroke; Fig.14 is the same in the reverse stage.

The second option differs from the first by the presence of groups of inlet openings 7 symmetrically positioned with respect to the pump axis, which are overlapped by two elastic valves 16 located between the inlet openings and the inlet channels of the separator. In a specific example, the separator 8 is trapezoidal, and the elastic valves 16 are mushroom-shaped.

The principle of operation of the vibration pump in the second embodiment is similar to the operation of the pump in the first embodiment.

Compared with the prototype and the first option, the proposed design provides an increase in consumer power.

Claims (10)

1. A vibration pump comprising an upper housing with a hydraulic chamber, which has inlets and a central outlet, an elastic valve and an elastic working member associated with an electric drive located in the lower housing, characterized in that a separator having a cylindrical shape is installed inside the hydraulic chamber , in the lower part of which a saddle is made for interaction with an elastic working body, moreover, inlet channels and an outlet channel formed by through with flow channels connected in the center to a common channel in the form of a pipe that is adjacent to the outlet of the hydraulic chamber, and the inlet channels are located on the sides of the outlet channel, in addition, an elastic valve in which the central hole is made is installed between the separator and the outlet pipe of the hydraulic chamber and the inlets are arranged in a circle around the outlet of the hydraulic chamber. 2. The pump according to claim 1, characterized in that the exhaust channel is formed by at least two oncoming channels. 3. The pump according to claim 1, characterized in that the oncoming channels form a right angle with the common channel. 4. The pump according to claim 1, characterized in that the oncoming channels are placed at an angle to each other. 5. The pump according to claim 1, characterized in that at the junction, the surface of the oncoming channels forms a flow guide made in the form of curved surfaces. 6. The pump according to claim 1, characterized in that the separator is installed in the housing through the sealing gaskets. 7. A vibration pump comprising an upper housing with a hydraulic chamber, which has a central outlet pipe, groups of inlets located on its sides, elastic valves and an elastic working member associated with an electric drive located in the lower housing, characterized in that inside the hydraulic chamber a separator is installed, in the lower part of which a saddle is made for interaction with an elastic working body, and inlet channels and an exhaust channel formed by a well are formed in the separator body znymi counterpropagating channels placed at an angle to each other and connected at the center in a common channel as a branch pipe, which is adjacent to the outlet of the hydraulic chamber, the inlet channels are placed on either side of the discharge passage and the elastic valve fitted between the inlets and the inlet of the separator channels. 8. The pump according to claim 7, characterized in that the exhaust channel is formed by at least two oncoming channels. 9. The pump according to claim 7, characterized in that at the junction, the surface of the oncoming channels forms a flow guide made in the form of curved surfaces. 10. The pump according to 7, characterized in that the separator is installed in the housing through the sealing gaskets.