RU199145U1 - Distribution outlet valve for diaphragm pump - Google Patents

Abstract

The utility model relates to the field of hydro and heat power engineering, where it can be used in devices for various purposes, such as diaphragm pumps, flow energy converters, as well as in systems for recovering excess pressure of the coolant to heat supply, where it can be used to create a pulsating mode of fluid movement. The control outlet valve for the diaphragm pump includes a hollow body with two inlet and one outlet, shock valves, rigidly mounted on the centering rod. The hollow body contains a rectangular cavity in which the return springs are located, holding the spherical clamps, alternately engaging with the bracket and the fixing pin, on which the centering rod, the bracket and the drive roller are rigidly connected, with the supports fixed in the roller cage with the help of a blind and a through nuts. The body also contains end nuts and additionally pressed discs with through channels into it. The rectangular cavity is connected to the covers by means of pins through spacers. The utility model makes it possible to improve the fixation of the shock valves in the open state due to the use in this design of the engagement between the bracket and the ball-shaped clamps. 1 ill.

Description

The utility model relates to the field of hydro and heat power engineering, where it can be used in devices for various purposes, such as diaphragm pumps, flow energy converters, as well as in systems for recovering excess pressure of the coolant to heat supply, where it can be used to create a pulsating mode of fluid movement.

Known impact assembly, including a hollow body with inlet and outlet openings for the outflow of the working medium, a shock valve, a rod installed in the sleeve with the possibility of reciprocating movement, a shaft with a cam, a spring, a retaining ring, a centering plug and a guide sleeve. The hollow body has two additional coaxial holes. The sleeve is made with through channels for the flow of the working medium along the stem. A shock valve is rigidly fixed at one end of the stem, and a retaining ring is installed at its other end. The spring is mounted on the stem between the bushing and the retaining ring. The bushing on the side of the retaining ring is rigidly connected to the inlet of the hollow body. The shaft is installed inside the hollow body with the possibility of rotational movement, where one end of the shaft is inserted into the centering plug fixed in the first additional hole of the hollow body, the second end of the shaft is brought out of the hollow body through the guide sleeve installed in the second additional through hole of the hollow body, the cam is connected with a rod with the possibility of converting the rotational movement of the shaft into a reciprocating movement of the rod. The inlet and outlet openings are made in the hollow body perpendicular to the axis of the additional openings. Through-slots are made in the centering plug along the shaft for the outflow of the working medium. Additionally contains a shock valve, a stem, a bushing with through channels, a spring and a retaining ring. In this case, the second rod is installed in the second sleeve with the possibility of reciprocating movement. At one end of the second stem, the second shock valve is rigidly fixed, and at its other end, a second retaining ring is installed. The second spring is mounted on the second stem between the second sleeve and the second retaining ring. Through channels in the second sleeve are made along the second rod. The second sleeve from the side of the second retaining ring is rigidly connected to the outlet of the hollow body, and the cam is connected to the second rod with the possibility of converting the rotational motion of the shaft into the reciprocating movement of the second rod. The utility model allows for alternating generation of momentum pulses of the working medium in one of its two into the device while providing external control of the opening and closing phases of the shock valves (RU 183591, F24D 3/02, F15B 21/12, publ. 09/26/2018).

Among the shortcomings of this design of the shock unit, one can note its insignificant throughput, complex adjustment of the rotation frequency of the shock unit, as well as the relatively low durability of the roller structure of the shock unit.

The closest in technical essence to the proposed technical solution is a shock unit, including a cylindrical body with inlet and outlet openings, a shock valve and, additionally, a second inlet, above which a second shock valve is located. The inlet holes are made coaxially along the centering rod installed in the cylindrical body on bushings with shock valves rigidly fixed at its ends. A movable saddle is screwed into the second inlet, connected by a worm gear with an adjusting screw (RU 114129, F24D 3/02, publ. 03/10/2012).

Among the disadvantages of this design, it should be noted that the stability of the operation is disturbed when the parameters of the working environment are changed, as well as the violation of the phases of alternating opening of the shock valves during the operation of the device.

The technical result of the distribution outlet valve for a membrane pump is to improve the fixation of the shock valves in the open state.

The technical result is achieved due to the fact that the control outlet valve for the diaphragm pump includes a hollow body with two inlet and one outlet, shock valves rigidly fixed to the centering rod. The hollow body contains a rectangular cavity in which the return springs are located, holding the spherical clamps, alternately engaging with the bracket and the fixing pin, on which the centering rod, the bracket and the drive roller are rigidly connected, with the supports fixed in the roller cage with the help of a blind and a through nuts. The body also contains end nuts and additionally pressed discs with through channels into it. The rectangular cavity is connected to the covers by means of pins through spacers.

The drawing shows the structure of the control outlet valve for a diaphragm pump.

The control outlet valve for a diaphragm pump includes a hollow body 1 with two inlet 2, 3 and one outlet 4 holes, shock valves 5, 6, rigidly fixed on the centering rod 7, a bracket 8, return springs 9, 10, holding ball-shaped clamps 11 , 12. Shock valves 5, 6 periodically come into contact with discs with through channels 13, 14, pressed into the hollow body 1. The fixing pin 15 rigidly connects the centering rod 7, the bracket 8 and the drive shaft 16, which is located in the supports 17, 18, fixed in roller cage 19 with blind 20 and 21 through nuts. Hollow body 1 contains a rectangular cavity 22, end nuts 23, 24 and covers 25, 26, connected to the hollow body 1 by means of pins 27, through gaskets 28, 29.

The control outlet valve for the diaphragm pump works as follows. Initially, to fill the hollow body 1 with a working medium, the inlets 2,3 are connected using end nuts 23, 24 with a source (not indicated in the drawing) of the working medium supply, and outlet 4 with a receiver (not indicated in the drawing) of the working medium ... After that, the working medium is fed into the hollow body 1 from its source, through the inlets 2, 3, and if the shock valve 5 is in the open state, then the shock valve 6 is closed (as shown in the drawing). In this position, the working medium from the inlet 2 passes through the hollow body 1, following through the disc with through channels 13, exits through the outlet 4. The open position of the shock valve 5 relative to the disc with through channels 13 is held by spherical retainers 11, which is located in the spherical cavity of the bracket 8 and is held by means of a return spring 9. In turn, the centering rod 7, the bracket 8 and the drive shaft 16 are rigidly connected by a fixing pin 15. The bracket 8 installed in the rectangular cavity 22 is sealed by means of covers 25, 26 connected by means of pins 27 , through gaskets 28, 29. Discs with through channels 13, 14 are pressed into the hollow body 1, and the shock valves 5, 6 are rigidly connected by the centering rod 7. When the drive roller 16 moves in the supports 17, 18, pressed into the roller cage 19, limited on the left is a blind 20, and on the right there is a straight through 21 with union nuts, from left to right, the shock valve 5 closes and opens Opening of the shock valve 6, and the spherical retainer 11 disengages from the bracket 8, and the spherical retainer 12 held by the return spring 10, falling into the spherical cavity of the bracket 8, fixes the shock valve 6 in the open position, which makes it possible to move the working medium from the inlet 3 pass through the hollow body 1, following through the disc with through channels 14 and exit the outlet 4, and then get into the receiver (not indicated in the drawing). In the future, the cycle is repeated anew.

In comparison with the known technical solution, the proposed one allows to improve the fixation of the shock valves in the open state.

Claims (1)

Distribution outlet valve for a diaphragm pump, including a hollow body with two inlet and one outlet, shock valves rigidly fixed on the centering rod, characterized in that the body contains a rectangular cavity in which return springs are located, holding ball-shaped clamps, alternately engaging with a bracket, and a fixing pin, on which the centering rod, the bracket and the drive roller are rigidly connected with supports fixed in the roller cage using blind and through nuts, the hollow body also contains end nuts and, additionally, discs with through channels are pressed into it, a rectangular cavity connected to the covers by means of pins through gaskets.

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