RU2107558C1 - Pneumatic dust remover - Google Patents

Abstract

FIELD: dust removal. SUBSTANCE: pneumatic dust remover has a compressed-air supply system, pistol-type grip furnished with a trigger mechanism for supply of compressed air, and a nozzle. It is furnished with a built-in oscillating valve forming a pulsating flow with periodically repeating pressure pulses and made in the form of a saddle valve with an extended body for movement in longitudinal direction, its one end is tightly engaged with the valve saddle under the action of a compression spring, and the other end is made in the form of a movable piston placed in a closed cylinder. One end of the valve facing the opposite side of the saddle is connected to an air conduit past the saddle valve by means of an internal duct passing through the extended valve body, and its opposite end is connected to the exhaust zone before the saddle located before the saddle valve by means of the internal cylinder valve. EFFECT: enhanced efficiency. 8 cl, 6 dwg

Description

 The present invention relates to a pneumatic dust removal device in which the dynamic effect of air is used to remove dirt and to clean, for example, agricultural implements, car undercarriages and for similar purposes where dirt, dust, oil and other contaminants are removed using only compressed air or in combination with cleaning agents such as water, cleaning liquids, sand, abrasive powder, etc., which are fed into the air stream immediately before it is sent to clean the second object, in order to obtain with the help of such an additive the effect of dissolving dirt and / or abrasive effect.

 The use of compressed air to remove dirt and for cleaning purposes is a well-known and widely used technology. The usual design is a device in the form of a pistol with an elongated air nozzle and an integrated shut-off valve, which provides a concentrated and adjustable air flow.

 Such devices, in particular, are known from SU N 1122494A, published 07.11.84, which describes a method and device for abrasive processing, as well as from GB N 2145219A "Manual device for cleaning with a jet of compressed air", published 03/20/85.

 The shut-off valve is usually adjusted manually. When a pneumatic dust extraction device is actuated, a concentrated air stream exits through its nozzle and is directed to the object being cleaned, as a result of which dirt and contaminants such as dust, earth, oil films, etc. can be loosened and removed. The ability of an air stream to loosen dried up dirt and various types of pollutants adhering strongly depends on the dynamic pressure exerted by the flow, i.e., on the flow velocity. The higher the speed, the better the cleansing effect.

 Nevertheless, the flow rate is limited by an allowable air pressure value, usually equal to 6 bar, and, therefore, an improvement in the cleaning action can be achieved only by increasing the air flow. The air consumption will be especially disproportionately large, and the cleaning method, therefore, uneconomical when removing a thick layer of adhering pollutant.

 The main objective of the present invention is the intention to improve the loosening and cleaning action of the dust extractor when removing particularly adhering pollutants and at the same time achieve an economical consumption of compressed air. In accordance with the invention, the objective is achieved by creating a dust extraction device described in the characterizing part of paragraph 1 of the claims.

 The principle of operation of the pulsating shut-off valve of the dust extraction device is based on the fact that instead of supplying compressed air in the form of a continuous flow through the nozzle, it is divided in place into a series of short pressure pulses, more precisely, it is a pulsating air flow with periodically repeated pressure pulses. These periodically repeating pulses, for example, with a frequency of 10-20 Hz, are based on the concentration of air pressure energy reduced to a unit time in such a way that the peak value of air pressure at individual pulses increases compared to the value of dynamic pressure that could be obtained in that if the same volume of air was continuously ejected through the nozzle. As already indicated, the value of the dynamic pressure of the air flow determines the ability of air to loosen adhering pollutants.

 In addition to higher dynamic pressures, the pulsating air flow also has the unexpected property of causing pollutants to vibrate when exposed to air pulses. Using certain types of pollutants as an example, it was practically shown that this action contributes highly to the cleaning effect of the dust extraction device, since vibration helps to loosen the substances, as a result of which cleaning occurs much faster, more thoroughly and with a more economical consumption of compressed air. The dust extractor claimed in the invention is thereby believed to be able to some extent replace traditional high pressure cleaning methods (water-based cleaning), while retaining their inherent advantages, both in terms of their economy and environmental friendliness.

 The principle of operation of the pulsating shutoff valve is as follows. In its original, closed / sealed position, the valve body is held tightly in the seat with a spring. After compressed air begins to flow (as a result of actuating the trigger mechanism of the device), the pressure on one side of the piston rises. The pressure exceeds the spring force and the valve opens, resulting in a simultaneous release of compressed air and a pressure drop. After that, the valve closes again and the whole cycle repeats. The pulsation continues until the compressed air enters the valve, i.e., until the trigger mechanism is activated. The valve, thus, alternately opens and closes the passage of air through the dust extraction device under the influence of static and dynamic pressure of compressed air.

 The pulsating action of the valve body implies the presence of an appropriate relationship between the valve dimensions, the mass of the valve body (moving mass) and the force characteristics of the spring. It is also essential that the valve body can move freely, i.e. with little friction. The pulse frequency depends on these factors in combination with the pressure value of the compressed air.

 In accordance with the invention, the piston seal may be made as described in paragraphs 2 and 3 of the claims.

 With this design, the sealing device meets the requirements to ensure free movement of the valve with low friction. It is advisable to provide the valve seat or the valve body itself with an elastic rubber coating described in paragraph 4, which serves to reduce noise and extend the life of the valve.

 The claimed dust extraction device can, like any conventional pneumatic dust extraction device, be used in combination with an ejector to supply liquid or granular material together with air (see paragraph 5 of the claims). The combination of pulsating compressed air and an additive comprising a substance for cleaning or dissolving, provides a significant increase in the cleaning effect. This technology is used in special cases when such an increase in efficiency is necessary.

 The invention will now be further explained with reference to the drawings, where in FIG. 1 is a side view of a pneumatic dust extraction device in accordance with the invention; in FIG. 2 is an enlarged sectional view of a nozzle of a given dust extraction device; in FIG. 3 is a separate enlarged longitudinal sectional view of a pulsating shut-off valve of the dust extraction device; in FIG. 4 - nozzle of the ejector, intended for use with the addition of liquid simultaneously with compressed air; in FIG. 5 is a similar ejector nozzle for sandblasting; in FIG. 6 - combined ejector-mixing valve with nozzles for the simultaneous supply of air and two different liquids.

 In the embodiment shown in FIG. 1, the dust extraction device consists of a handle 1 (pistol type) with a release lever 2 and a safety clip 3, a retractable cylinder 4 and a replaceable nozzle pipe 5, which is equipped with a replaceable nozzle tip 6. The latter is shown separately in FIG. 2. Handle 1 includes a shut-off valve, not shown, that opens with the release lever 2, and a pulsating discharge valve. The discharge valve is integrated in the handle portion designated 1a. The air supply to the dust extraction device is carried out through the rod clutch 7. The pipe 5 of the nozzle is mounted on the handle 1 using the knurled nut of the nozzle 8.

 In FIG. 3 is a sectional view of a pulsating discharge valve. The main element of the discharge valve is a seat valve, the seat of which is indicated by the number 9, and the valve body 10. The valve body is made in the form of an elongated symmetrical body of revolution equipped with an internal channel. One end of the valve body forms a cone-shaped sealing disk 11, which fits tightly in the seat 9. The cone-shaped element 11 is provided with a rubber coating 11a vulcanized thereto. The opposite end of the valve body 10 is a piston 12 inserted in the cylinder 13. An elongated cylindrical rod 14 is located between the piston 12 and the cone-shaped element 11 of the valve body.

 The internal channel in the valve body, indicated by the numeral 15, is used to connect the rear of the portion 13a of the cylinder 13 to the air duct 16 behind the seat valve, i.e., to the extendable cylinder 4 and the nozzle pipe 5. The valve body is pressed against the seat using a cylindrical compression spring 17 placed in the cylinder 13 behind the piston 12.

 The opposite end 13b of the cylinder is connected by means of an eccentrically located inner channel 18 to the air chamber 19 located immediately in front of the seat valve from its outlet side. The direction of flow through the valve is shown by arrows 20.

 A low friction O-ring consisting of a Teflon disk 21 and a rubber O-ring 22 is fitted to the valve piston 12. The rubber O-ring serves as a support disk for the Teflon ring, which, due to contact with the cylinder wall, ensures that the piston is sealed.

 The dimensions of the valve, the size and weight of the valve body, the characteristics of the spring, the area of the passageway of the duct, etc., are selected from the conditions for obtaining the most pronounced ripple effect that occurs automatically immediately after the air flow is open (as a result of actuating the trigger 2 ) The explanation of the pulsation effect was given earlier and will not be repeated here. During the pulsation of the valve body, the passage of compressed air through the seat valve opens and closes, which creates pulses of compressed air with cyclically repeated pressure pulses. The impact of pressure pulses is transmitted from the seat valve 9.11 and then through the retractable cylinder 4, the pipe 5 of the nozzle 6 to its tip.

 By replacing the pipe 5 of the nozzle 6, the dust extraction device may be provided with various types of ejectors as shown in FIG. 4,5 and 6. In FIG. 4 shows a combined ejector-mixing valve for a liquid. The liquid is supplied through the hose 23. The pipe 5 of the nozzle 6 of the dust extraction device is indicated by 24. The shut-off valve, which is part of the ejector-mixing valve, cuts off the liquid supply under the influence of the liquid pressure and again automatically opens when the compressed air supply is opened.

 The mixing valve can also serve as an ejector, i.e. with a pressureless flow of fluid. In this case, the liquid is sucked into the ejector from a tank or container not shown due to the usual ejector effect when compressed air is supplied through the ejector.

 The amount of liquid can be adjusted using a flow control valve located at the inlet of the ejector nozzle in the case of a mixer valve and an ejector valve. The flow valve is adjusted using the wing nut 23a.

 In FIG. 5 shows an ejector used in sandblasting. Sand through the tube peak 25 is absorbed into the nozzle due to the electronic effect. By adjusting the air suction through the suction hose (the so-called "unorganized air"), the amount of sand flow can be adjusted in accordance with specific requirements. The adjustment is carried out using a flow rate valve 25a integrated in the upper part of the sandblasted peaks.

 In FIG. 6 shows an injection-mixing valve 26, which, in addition to the compressed air supply pipe 27, is provided with two additional openings 28 and 29 for mixing water and liquid chemicals, respectively. The design allows air + water + chemicals to be mixed in the same stream. This combination is applicable, among other things, to perform work that requires disinfection or cleaning of grease.

The mixing valve can be used in the following combinations:
1) only air (both fluid inlets are plugged or otherwise plugged),
2) air + adjustable volume of water,
3) air + adjustable volume of water + adjustable volume of chemicals,
4) air + adjustable volume of chemicals
5) air + water soluble chemicals + adjustable concentration of chemicals,
6) air drying after cleaning with water / chemicals.

 The invention is not limited to the embodiments shown and explained above. Other types of pulsating discharge valves are possible. The original idea of the invention is to convert the static energy of compressed air into a pulsating concentrated air stream, the individual pressure pulses of which have high dynamic energy.

Claims (8)

 1. A pneumatic dust collecting device including a compressed air supply system, a pistol portion forming a handle equipped with a trigger for supplying compressed air, and a nozzle, characterized in that it is equipped with a built-in oscillating valve for generating a pulsating flow with periodically repeating pressure pulses and made in the form a valve seat with an elongated body with the ability to move in the longitudinal direction, one end of which is in close contact with the valve seat under the action of the compression spring, and the other end is made in the form of a movable piston located in a closed cylinder, one end of which, facing the opposite side of the seat, is connected to the duct behind the seat valve through an internal channel passing through the elongated valve body, and its opposite end is connected with an outlet zone in front of the seat, located in front of the seat valve through the internal channel of the cylinder.  2. The device according to claim 1, characterized in that the frequency of the pulsating flow is in the range of 2-50 Hz.  3. The device according to claim 1, characterized in that the movable piston forming one end of the elongated valve body is provided with a sealing ring with a low coefficient of friction and high sliding qualities made, for example, of Teflon or similar material.  4. The device according to claim 3, characterized in that the o-ring is made of a Teflon disk resting on a rubber o-ring located in the annular groove of the piston.  5. The device according to claim 1, characterized in that the end part of the elongated valve body resting on the seat is made of elastic material or coated with it, preferably polyurethane, synthetic rubber or similar wear-resistant elastic material.  6. The device according to claim 1, characterized in that the pulsating valve is integrated into the pistol portion, and ejectors for supplying cleaning liquid, water, sand or other mixtures to the pulsating stream of compressed air are connected to the nozzle.  7. The device according to claim 1, characterized in that the ejectors connected to the nozzle feed the cleaning liquid, water, sand or other mixtures into the pulsating stream of compressed air.  8. The device according to claim 7, characterized in that the ejectors are equipped with built-in shut-off valves.

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