RU2823399C1 - Pulse supercharger - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: invention relates to heat engineering and can be used in pulse supercharger. In the pulse supercharger, the hollow housing and the elastic diaphragm are made in the form of pipes inserted into each other, which are installed on the pulse circulation pipeline of the working medium coaxially with it, which, in turn, is located inside the hollow housing and there are perforated holes on it, the ends of the elastic diaphragm pipeline are clamped between the inlet and outlet fastening flanges rigidly fixed on each of the ends of the hollow housing, and corresponding mating inlet and outlet flanges pressed to each other by means of bolted joints installed in combined fastening and mounting holes, inlet branch pipe of working medium is installed in through central hole of inlet mating flange and is rigidly fixed with it, working medium outlet branch pipe is installed in the through central hole of the outlet mating flange and is rigidly fixed with it, and ends of pipeline of pulse circulation of working medium are installed on inlet and outlet nozzles of working medium from inner side of hollow housing.

EFFECT: higher efficiency of pulse supercharger.

1 cl, 1 dwg

Description

Field of technology to which the invention relates

The invention relates to the field of thermal power engineering and can be used in heat supply systems with oscillatory circulation of coolant to transform the available pressure between the working and pumped media.

State of the art

A pulsed supercharger-heat exchanger is known (patent RU No. 2702064, published 10/03/2019, IPC F28F 27/00, F28D 7/00), including a hollow body, an inlet pipe of the working medium, check valves for the inlet and outlet of the pressurized medium, an outlet pipe of the working medium , manifolds for the inlet and outlet of the injected medium, connected on the one hand to the inlet and outlet pipes of the injected medium, and on the other, through quick-release threaded connections to copper envelopes, which are installed in a hollow body and have damping elements made of vibration-damping material, the hollow body has a lid , connected to it by means of studs, and an impact unit is installed on the outlet pipe of the working medium.

Among the disadvantages of this design, it should be noted the relatively low efficiency of using the energy of hydraulic shock in relation to fluid injection.

A pulse supercharger is known (patent RU No. 168152, published 01/19/2017, MPK F24D 3/00, F04B 43/00, F04F 1/00, F04F 7/00), including a hollow body, two diaphragms, inlet and outlet check valves, a control valve, a hydraulic accumulator, a drain valve and a connecting pipe, with the diaphragms installed inside a hollow body to form three hydraulically isolated zones. The first zone, limited by the hollow body and the first diaphragm, is connected to the inlet and outlet check valves, a hydraulic accumulator is connected to the second zone, limited by the hollow body and two diaphragms, through a control valve, the third zone, limited by the hollow body and the second diaphragm, is connected to the connecting pipe, and the drain valve is installed between the control valve and the hydraulic accumulator

The disadvantages of this technical solution are the relatively low productivity and design complexity.

The closest in technical essence to the proposed invention is a pulse supercharger as part of a water-lifting device (RU patent for PM No. 99553, published November 20, 2010, IPC F04F 7/00), which includes a hollow body, which has an elastic diaphragm installed in its cross-section on one side connected to the pipeline for pulsed circulation of the working medium, and on its other side connected to the check valves of the inlet and outlet of the pumped medium, while the elastic diaphragm is pressed to the pipeline for the pulsed circulation of the working medium by a spring located in the supercharger.

The disadvantage of this technical solution is low productivity due to the relatively small surface of the elastic diaphragm, which does not allow the most complete use of the pulsed increase in pressure in the supply pipeline at the time of the local water hammer created and its wave propagation in relation to ensuring the circulation of the injected liquid.

Disclosure of the invention

The technical objective of the invention is to increase the performance of a pulse supercharger.

The technical result consists in increasing the contact area between the working and injected medium through the elastic diaphragm separating them.

This is achieved by the fact that a well-known pulse supercharger containing a hollow body, which on one side of an elastic diaphragm installed inside it is connected to a pulse circulation pipeline of the working medium, and on its other side is connected to check valves of the inlet and outlet of the pumped medium, equipped with inlet and outlet mounting flanges , each of which has radial mounting holes, inlet and outlet counter flanges, each of which has one through central hole and radial mounting holes in the number of radial mounting holes on the corresponding inlet and outlet mounting flanges, inlet and outlet pipes of the working medium, as well as bolted connections, wherein the hollow body and elastic diaphragm are made in the form of pipes inserted into each other, which are installed on the pulse circulation pipeline of the working medium coaxially with it, which, in turn, is located inside the hollow body and has perforated holes on it, the ends of the elastic diaphragm pipeline are clamped between the inlet and outlet mounting flanges, rigidly fixed to each of the ends of the hollow body, and the corresponding mating inlet and outlet flanges, pressed against each other by means of bolted connections installed in combined mounting and mounting holes, the inlet pipe of the working medium is installed into the through central hole of the inlet mating flange and is rigidly fixed to it, the outlet pipe of the working medium is installed in the through central hole of the output mating flange and is rigidly fixed to it, and the ends of the pulse circulation pipeline of the working medium are installed on the inlet and outlet pipes of the working medium from the inside of the hollow housings.

Brief description of drawings

The essence of the invention is illustrated by the drawing, which shows the proposed pulse supercharger.

Carrying out the invention

The pulse supercharger contains a tubular hollow body 1 with a tubular elastic diaphragm 2 installed inside it, which are installed on the pulse circulation pipeline of the working medium 3 coaxially with it in the form of coaxial cylinders. Moreover, on one side of the elastic diaphragm 2, the hollow body 1 is hydraulically connected to the pulse circulation pipeline of the working medium 3, and on the other side it is connected to the check valves of the inlet 4 and outlet 5 of the injected medium.

The pulse supercharger also contains: inlet 6 and outlet 7 mounting flanges, each of which has radial mounting holes 8; inlet 9 and outlet 10 counter flanges, each of which has one through central hole 11 and radial mounting holes 12 in the number of radial mounting holes 8 on the corresponding inlet 7 and outlet 8 mounting flanges; inlet 13 and outlet 14 pipes of the working medium; bolted connections 15.

On the pulse circulation pipeline of the working medium 3, there are perforated holes 16. Moreover, the number of radial mounting holes 8 on the inlet 6 and outlet 7 mounting flanges is equal to the number of radial mounting holes 12 on the corresponding inlet 9 and outlet 10 counter flanges, and their location is the same. The inlet 6 and outlet 7 mounting flanges are rigidly and hermetically fastened to each of the ends of the hollow body 1. The inlet pipe 13 of the working medium is hermetically installed in the through central hole 11 of the inlet counter flange 9 and is rigidly fixed to it, for example, by welding. The outlet pipe 14 of the working medium is hermetically installed in the through central hole 11 of the output counter flange 10 and is rigidly fixed to it, for example, by welding.

In this case, the ends of the pipeline for pulsed circulation of the working medium 3 are installed on the inlet 13 and outlet 14 pipes of the working medium from the inside of the hollow body 1. And the ends of the pipeline of the elastic diaphragm 2 are clamped between the inlet 6 and outlet 7 mounting flanges and the corresponding mating inlet 9 and outlet 10 flanges , pressed against each other by means of bolted connections 15 installed in combined mounting 8 and mounting 12 holes.

The pulse supercharger works as follows.

First, the inlet pipe of the working environment 13 is connected to the source of supply of the working environment, and the outlet pipe of the working environment 14 is connected to the receiver of the working environment (the supply source and the receiver of the working environment are not indicated in the drawing). The inlet of the injected medium is connected to its source through the check valve of the inlet 4, and the output of the injected medium is connected to its receiver through the check valve of the outlet 5 (in the drawing, the supply source and the receiver of the injected medium are not indicated). Then, during the initial stationary supply of the working and pressurized medium, air is removed from the device, which can be ensured, including by loosening the bolted connections 15 for this purpose and/or using automatic air vents (not shown in the drawing). After this, the device is completely ready for use.

During the initial circulation of the working medium through the pulsed circulation pipeline of the working medium 3 in a stationary mode, the tubular elastic diaphragm 2 is pressed against its outer surface with perforated holes 16 under conditions of excess of the available pressure of the injected medium relative to the available pressure of the working medium. This position of the elastic diaphragm 2 is optimal for starting the pulse supercharger into operation.

With the subsequent transition to oscillatory (pulse or pulsating) circulation of the working medium through the pulsed circulation pipeline of the working medium 3, which can be achieved by using special devices for converting flows, for example, pulsators and impact units (not shown in the drawing), a change in the open cross-section will occur tubular elastic diaphragm 2 under the influence of the reverse flow of the working medium flowing in alternating directions through the perforated holes 16.

Moreover, at the moment of a pulsed increase in pressure (for example, at the moment of a positive wave of local water hammer) in the pulse circulation pipeline of the working medium 3, the tubular elastic diaphragm 2 is moved by the working medium coming from the internal cavity of the pulse circulation pipeline of the working medium 3 to its outer side through perforated holes 16 in a hydraulic cavity limited by the tubular elastic diaphragm 2 itself, the outer surface of the pipeline for pulsed circulation of the working medium 3, inlet 9 and output 10 counter flanges, as well as perforated holes 16. This is the movement of the tubular elastic diaphragm 2 in the direction from the outer surface of the pipeline for pulsed circulation of the working medium 3 to the inner surface of the hollow body 1 occurs when the injected medium is simultaneously displaced from the hydraulic cavity, limited by the tubular elastic diaphragm 2 itself, check valves of the inlet 4 and outlet 5 of the injected medium, inlet 6 and outlet 7 mounting flanges and the inner surface of the hollow body 1, through the outlet check valve 5 to her receiver.

At the moment of a pulsed decrease in pressure in the pulse circulation pipeline of the working medium 3 (for example, at the moment of a negative wave of local water hammer), the tubular elastic diaphragm 2 moves from the inner surface of the hollow body 1 to the outer surface of the pulse circulation pipeline of the working medium 3 when the working medium flows out of the hydraulic cavity limited by the tubular cavity itself elastic diaphragm 2, the outer surface of the pipeline for pulsed circulation of the working medium 3, inlet 9 and output 10 mating flanges, as well as perforated holes 16, inside the pipeline for pulsed circulation of the working medium 3 through perforated holes 16. This is the movement of the tubular elastic diaphragm 2 in the direction from the inner surface hollow body 1 to the outer surface of the pipeline for pulsed circulation of the working medium 3 occurs when the injected medium is simultaneously suctioned into the hydraulic cavity limited by a tubular elastic diaphragm 2, check valves of the injected medium inlet 4 and outlet 5, inlet 6 and outlet 7 mounting flanges and the inner surface of the hollow body 1, through the check valve of the inlet 4 of the injected medium from its source.

With a subsequent cycle of increasing and decreasing the pressure of the working medium in the pulse circulation pipeline of the working medium 3, the process of supplying the injected medium will be repeated in the sequence described above and will continue as long as oscillatory (pulse and/or pulsating) circulation of the working medium through it is ensured.

The presence of bolted connections 15 installed in the combined radial mounting holes 8 of the inlet 6 and outlet 7 mounting flanges and the radial mounting holes 12 of the inlet 9 and outlet 10 counter flanges makes it possible to disassemble the device in order to replace the tubular elastic diaphragm 2 that has spent its service life and/or device maintenance. Access to the internal cavity of the hollow body 1 is provided, including when removing the inlet 9 and outlet 10 mating flanges when disconnecting the inlet 13 and outlet 14 pipes of the working medium and the pulse circulation pipeline of the working medium 3 itself from its source and receiver.

Installation of a pipeline for pulse circulation of the working medium 3 inside the hollow body 1 on the inlet and 13 and outlet 14 pipes of the working medium allows not only to simplify the technological production of structural elements of the device, since in this case its length will be determined by the length of the hollow body 1, but also the assembly, as well as and device maintenance.

Since in the proposed design, the inlet pipe 13 of the working medium and the inlet mating flange 9, as well as the outlet pipe 14 of the working medium and the output mating flange 10 form single pairs of sealed structural elements, this allows the device to be assembled and prepared for operation without the use of any additional sealing materials.

The inlet 13 and outlet 14 pipes of the working medium also allow for ergonomic connection of the device into the section of any pipeline, the energy of the outflow of the working medium in which is supposed to be used in relation to organizing the supply of the injected medium from its source to the receiver.

As a result of the use of the proposed design of a pulse supercharger, an increase in the productivity of the device for the pumped medium is ensured, which is achieved by an increased contact area between the working and the pumped media through the elastic diaphragm separating them. The relative simplicity of the design simplifies its maintenance and increases the reliability of use.

Claims (1)

A pulse supercharger containing a hollow body, which on one side of an elastic diaphragm installed inside it is connected to a pulse circulation pipeline of the working medium, and on the other side it is connected to check valves for the inlet and outlet of the pumped medium, characterized in that it is equipped with inlet and outlet mounting flanges , each of which has radial mounting holes, inlet and outlet counter flanges, each of which has one through central hole and radial mounting holes in the number of radial mounting holes on the corresponding inlet and outlet mounting flanges, inlet and outlet pipes of the working medium, as well as bolted connections, wherein the hollow body and elastic diaphragm are made in the form of pipes inserted into each other, which are installed on the pulse circulation pipeline of the working medium coaxially with it, which, in turn, is located inside the hollow body and has perforated holes on it, the ends of the elastic diaphragm pipeline are clamped between the inlet and outlet mounting flanges, rigidly fixed to each of the ends of the hollow body, and the corresponding mating inlet and outlet flanges, pressed against each other by means of bolted connections installed in combined mounting and mounting holes, the inlet pipe of the working medium is installed into the through central hole of the inlet mating flange and is rigidly fixed to it, the outlet pipe of the working medium is installed in the through central hole of the output mating flange and is rigidly fixed to it, and the ends of the pulse circulation pipeline of the working medium are installed on the inlet and outlet pipes of the working medium from the inside of the hollow housings.