UA20571U - Pneumatic pulse device for cleaning of conduits - Google Patents

Abstract

A pneumatic pulse device for cleaning of conduits contains a housing, an annular nozzle, a working chamber for accumulation of working agent, a piston with central dosage channel, a seal.

Description

Description of the invention

The proposed useful model applies to the field of cleaning pipelines in cottage villages, chemical, 2 food, industrial enterprises, in the housing and communal economy when cleaning water intakes, water pipes, rain and storm sewers, chimneys, wells, heating boilers, hot and cold water supply, heating plants , ventilation shafts, garbage pipelines, heat supply pipelines. The device can also be used in the gas industry when cleaning main gas pipelines. 70 Today, the following devices are used in the market of sewage pipeline cleaning services:

For cleaning internal pipelines up to 100 mm, high-pressure machines such as "KRANSLE", "KERKHER", etc., as well as mechanical machines similar to the German "OTENBERGER" are used perfectly.

From 100 to 200 mm - the equipment is similar to the German RODGET of the KROLL company.

From 200 to 400 mm - also a RODGET, but only of the appropriate pressure and water flow. The same diameters of external 12 sewers can also be cleaned with the KO-502, KO-564, etc.

A known device for cleaning hollow products, containing a housing with an internal channel for supplying the working agent, the front part of which has an annular nozzle for pumping the working agent, located at an angle to the longitudinal axis of the housing and directed to its rear part, made with the possibility of connecting to hose see patent of the Russian Federation Mo2079381 Published: 1997.05.201.

This technical solution, as the closest in terms of technical essence and functional purpose, was accepted by me as a prototype.

The disadvantage of the known device is the low quality of pipeline cleaning with solid deposits on its inner walls.

The basis of the useful model is the task of creating such a design of a pneumatic impulse device for 29 pipeline cleaning, by improving the known ones, which would improve the quality of cleaning. This problem is solved as follows: a pneumatic impulse device for cleaning pipelines, which includes a housing consisting of front, middle and rear parts, a ring nozzle located at an angle to the longitudinal axis of the housing and directed to its rear part, which is made with the possibility connection to the hose, according to the useful model, additionally contains a working chamber for accumulating the working agent, located in the front part of the housing, and a ring nozzle with exhaust holes, located in the rear part of the housing, in which a piston with a central dosing channel is additionally located in such a way that it is capable of longitudinal, limited movement inside the housing and is provided with a sealing material for sealing in places of longitudinal movement. As the material of the seal, fluoroplastic or capron is used, and the acrobatic agent (compressed air with a pressure of 80 to 200 atm is used. The angle of inclination of the ring nozzle with exhaust holes in the rear part of the housing to its longitudinal axis is 452. In addition, the pneumatic impulse device contains a self-contained, built-in , a dosing system for portioned air release.The piston has a front and a back part.

The essence of the useful model is explained by the drawing, where in Fig. the pneumoimpulse device as a whole is shown in section: "

The pneumatic impulse device for cleaning pipelines contains a housing 1 with an internal working chamber 2 Ш 70 for accumulating the working agent, made in the form of a cup, the front part of which has a perpendicular c to the longitudinal part of the housing opening 4 for connecting a safety cable. The middle part 1" of the case is made in the form of a two-sided threaded adapter 5 for connection when assembling the front and back parts of the device case. The rear part 6 has a ring nozzle with exhaust holes 7 located at an angle of 452 to the longitudinal axis of the housing and directed to its rear part, made with the possibility of connecting to a hose 8. Inside the housing, there is a piston 9 with a central dosing channel (jet) 10 , with the front part 11 and the rear part 12, which is capable of limited longitudinal movement (c) inside the cylindrical body. In the device, fluoroplastic rings 13 and 13a are used as a sealing material for sealing in places of longitudinal movement of the piston. All parts of the body are made of carbon steel, the piston is made of bronze. Compressed air is used as a working agent. -and 50 The pneumatic impulse device for cleaning pipelines functions as follows. For different diameters of pipelines, it is necessary to use a device with a certain volume of the working chamber (2). After that, a high-pressure main hose (8) is connected to the device and compressed air is supplied, the device itself is introduced into the pipeline cleaning zone.

The essence of the pneumatic pulse is that in a flowing or weakly filled system (pipeline), a certain amount of compressed to high pressure air enters the environment in a very short period of time. Jets of air falling into a liquid medium, thanks to its resistance, form a bubble almost instantly. Inside the air bubble at the time of its creation, the pressure is much higher than the ambient pressure, which causes the bubble to expand rapidly. At the same time, the liquid surrounding the bubble moves at a high speed. When the bubble expands, the pressure in it drops to a value lower than the ambient pressure, and at some point in time the bubble begins to contract. When the bubble is compressed, the pressure in it increases, reaching a critical value, after which expansion begins again. Thus, with a pneumatic pulse, a pulsating bubble appears, which disrupts the wave process that destroys deposits in the pipeline. The effectiveness of pneumatic projectiles largely depends not only on the force of the impulse, but also on their frequency. This can be explained by the fact that with a high frequency of pulses, the waves reflected from the pipeline wall cut off the first most powerful compression wave b5. Based on this, it is necessary to use the optimal pulse frequency for each specific case. The frequency of pulses depends on both the pressure and the volume of the working chamber (charge) of the device. Based on this, it is necessary to have a set of different pneumatic impulse devices (with different charge sizes) in the set for working with different diameters of the pipeline and with deposits of different hardness.

Solid, dry deposits that cannot be cleaned by the above-mentioned device (when there is a denser liquid medium in the system) are also cleaned according to the pneumatic pulse principle. For each diameter of the pipe being cleaned, a pneumatic impulse device (of a certain design, adapted to the given size) is used.

Analysis of the characteristics of the pneumatic pulse with different diameters of the pipelines allows us to conclude about the need to increase the "charge (volume of the working chamber) or air pressure in the working chamber of the 7/0 pneumatic pulse device with an increase in the diameter of the pipeline.

Controlled, clearly directed, dosed along the axes of action on the deposition of a pneumopulse, forms a "cold" shock wave. Due to the fact that the nature of the deposits and the pipe material have different densities, the shock wave propagates through them at different speeds. This leads to the fact that a resonance effect is observed at the interface between the pipe and the deposits, which layers these structures. When "undermining" the adhering layers of formations, and 7/5 Separating it from the pipe walls, a milling effect of cleaning is added to the effect of the pneumatic impulse. During the operation of the device in a liquid-filled pipeline, a shock wave caused by a pneumatic impulse, propagating in a dense environment, causes the effect of hydrocavitation, in which the smallest bubbles formed on the construction material act as an abrasive tool.

The pneumatic pulse itself is formed during the operation of the device in this way.

Air, entering the device through the main high-pressure hose, which is attached by a threaded connection to the fitting 8, presses on the back of the piston 12, displacing it forward. Moving forward, the front part of the piston 11 enters the fluoroplastic seal ring 13 and blocks the connection of the working chamber 2 with the exhaust holes 7 with the working body of the piston 9. Air, continuing to flow through the hose (not shown in the drawing) through the fitting 8, passes through the central dosing channel (jet) 10, and fills the working chamber 2. In chamber 2, the pressure rises, at first equilibrium occurs on both sides of the piston 9, but the pressure in the working chamber at a certain moment becomes critical, greater than in the back of the device 8, and it rejects From the pistons to the back of the device, allowing the air from the working chamber 2 of the device through the exhaust holes 7 under high pressure to escape outside. Inciting the pressure from the working chamber 2 through the exhaust holes 7, at which point the equilibrium is first established again, and then its shift to the right side, to the rear part "- from the piston 12. The piston will again mix to the front part of the device 3, again, blocking the connection between the working chamber 2 and the exhaust holes 7, the working chamber 2 is again filled with air to the critical pressure and - the cycle is repeated again. The exhaust frequency depends on the pressure: the higher it is, the faster the working chamber 2 is filled; from the diameter of the dosing channel 10: the larger it is, the faster the filling, the faster the cycle. The power of the pneumatic pulse depends on the amount of air that is ejected in one cycle. at

Thus, increasing the size of the working chamber 2 of the device increases the power of the pneumatic pulse. with

Claims (6)

The formula of the invention " 1. Pneumoimpulse device for cleaning pipelines, containing a body consisting of the front, middle and rear parts, a ring nozzle located at an angle to the longitudinal axis of the body and directed to its rear part, which is made with the possibility of connecting to a hose , which differs in that it 1" additionally contains a working chamber for accumulating the working agent, located in the front part of the housing, and an annular nozzle with exhaust holes is located in the rear part of the housing, which additionally houses a piston with a central dosing channel in such a way that it capable of limited longitudinal movement d) inside the case and equipped with a sealing material for sealing in places of longitudinal movement. 2. Pneumoimpulse device according to claim 1, which differs in that fluoroplastic or kapron is used as a sealing material. sl 3. Pneumoimpulse device according to claim 1, which differs in that compressed air with a pressure of 80 to 200 atm is used as a working agent. - 4. The pneumoimpulse device according to claim 1, which is characterized by the fact that the angle of inclination of the ring nozzle with the exhaust cheek holes in the rear part of the case to its longitudinal axis is 459. 5. A pneumoimpulse device according to claim 1, which is characterized by the fact that it contains an autonomous, built-in, dosing system for portioned air release. 6. The pneumoimpulse device according to claim 1, which differs in that the piston has a front and a back part. p. 60 b5