DE3127013A1 - METHOD FOR COMPRESSED AIR JET, AND JET FOR IMPLEMENTING THE METHOD - Google Patents

Abstract

1. A method of sand-blasting wherein particulate ejecting medium ist delivered to a carrier gas stream, propelled and accelerated by said carrier gas stream, and ejected to the surface to be treated, wherein an additive gas stream carrying an additive substance, preferably water, is fed to said carrier gas stream, and wherein a feed conduit for the particulate ejecting medium is followed by a frustoconically tapered region, characterized in that said additive gas stream carrying said additive substance is fed to said carrier gas stream at a location in the frustoconically tapered region where speed and acceleration of the particulate ejecting medium are still low.

Description

Gesthuysen & Leutwein

81.154.ne

Essen, October 8th, 1981

concerning the company

Patent application

Ernst Peiniger GmbH Company for building protection

At the radio tower 2

5090 Leverkusen 1

"Process for compressed air blasting and blasting device for carrying out the process"

Patent Attorneys ■ Dipl.-lng. Hans Dieter Gesthuysen · Dipl.-Phys. Dr. Klaus Leutwein Essen 1, Huyssenaliee 15, phone: 02 01/23 3917, telex: 08/57 9990

The invention relates to a method for compressed air blasting, with a granular Blasting media are introduced into a flow of air and conveyed by the flow of air, accelerated and blown against a surface to be treated is and the laden air stream with a preferably liquid, preferably wetting the blasting agent additive, in particular Water, loaded additional air stream is added, in particular is injected into the carrying air stream loaded with the blasting agent, - as well as a blasting device to carry out this procedure.

In a known method of the type described above, by adding the additional air stream loaded with a liquid additive, a humidifying. th of the blasting agent achieved (see. DE-OS 27 Ά 318). This moistening can be dosed in such a way that the amount of the added liquid additive is just sufficient to bind the developing dust or to prevent or at least reduce the development of dust when the blasting agent hits the surface to be treated. However, the amount of additive added is not so great that the additive precipitates on and runs off the surface to be treated. The known method described above is therefore to be located between “dry blasting”, that is to say compressed air blasting, for example with dry sand, and between “wet blasting” and is referred to as “wet blasting”.

In the known process from which the invention is based, the addition takes place of the additional air flow loaded with the liquid additive at a nozzle narrowing! Ie of the nozzle area of the blasting device, with this method is carried out. Here the air flow has its highest speed and thus its lowest static pressure. This low static pressure is used to suck in the additional air flow. This will stop the addition of the the additional air flow loaded with the additive is extremely simple; she but cannot be controlled to the required extent.

When blasting with compressed air, the highest possible impact speed of the Blasting media aimed at the surface to be treated. That in a supply line jet conveyed by means of flight conveyance through the air flow

medium is in the nozzle area of the blasting device in which the static pressure the air flow is converted as much as possible into kinetic energy, entrained by the air flow accelerated in this way, whereby the blasting media should reach a speed that is as close as possible to the speed range of the carrying air flow.

Due to the different specific weights of the air flow and of the abrasive, the air flow is accelerated much more than the abrasive it carries with it. One tries to achieve this effect to counteract, for example, that the conversion of the static pressure of the carrier air flow into kinetic energy over a relatively long period of time Path takes place in which the nozzle area has a relatively long constriction area having. But also when a relatively long acceleration section is provided in the form of a long narrowing area the speed of the abrasive remains significantly behind the speed of the air flow. The speed of the abrasive is further reduced by the fact that the abrasive experiences an increase in mass due to the liquid additive with which it is moistened, so that its actual acceleration is further reduced.

The disadvantage of the known, previously described method is, in particular, that the place of addition of the air stream conveyed with the additive additive is located at a point of the nozzle area of the blasting device, in which a large acceleration of the blasting agent is to be achieved at the same time. This is the rrit de ™ additive for wetting the abrasive Available time very short; the desired, completely closed envelope of the blasting agent with the liquid additive is among these Circumstances not achieved. As a result, the dust binding is also to be treated Surface is not always satisfactory unless an "overdose" of additive is used.

The object of the invention is now the method described above To improve the type and the blasting device working according to this method, that on the one hand a targeted, easily controllable and complete conversion

casing 4 "= of the blasting agent with the preferably liquid additive The smallest amount of this additive is possible, but on the other hand the acceleration of the blasting abrasive is influenced as little as possible by the addition of the additive by the air flow.

The method according to the invention, in which the object indicated above is achieved is, is initially characterized in that the addition of the with the additive laden additional air flow in a local area of the laden Carrying air flow takes place in which the speed and acceleration of the abrasive is low. According to the invention, the location at which the acceleration of the blasting agent is carried out by the air flow, and the place at which the addition of the additional air stream loaded with the additive takes place, spatially separated from one another. This ensures that the addition of the additive does not interfere with the acceleration process and vice versa, so that the two processes, i.e. both the acceleration and the addition of the additive can be optimally designed for itself.

Since, according to the invention, the addition of the additive takes place before the actual If the blasting agent is accelerated, the blasting agent already has the increase in mass when it enters the actual acceleration section experience of moistening and the abrasive is accelerated in the moistened state. Since the acceleration is undisturbed by external influences expires, the greatest possible acceleration of the previously moistened blasting agent achieved. In particular, however, prevail in the local area of the additional air flow at which, according to the invention, the addition of the additive loaded additional air flow should take place, with respect to manageable proportions the trajectory of the abrasive, so that the moistening of the abrasive can take place much more precisely at this point than in the area the nozzle constriction. The teaching of the invention thus enables an advantageous one Decoupling of moistening and acceleration, optimal control of the two processes without mutual interaction, more precise moistening of the abrasive and an improved impact speed of the abrasive on the surface to be treated.

The addition advantageously takes place in the process according to the invention of the additional air flow loaded with the additive at the beginning of the acceleration section of the abrasive. At this point, a certain, but only small acceleration of the abrasive has already taken place, so that a Backlog of the following blasting agent due to the moistening of the blasting agent avoided and clogging prevented.

According to a further teaching of the invention, which is of particular importance, the blasting media becomes self-rotating and / or rotating in the injection area relative to the direction of flow of the air flow, in particular a helical rotary movement given. This becomes an all-round one Envelopment of the abrasive with the additive facilitated. The rotation of its own of the blasting agent or the rotary movement of the blasting agent relative to the direction of flow of the support air stream can easily be through a eccentrically occurring addition of the additional air flow can be caused.

A blasting device suitable for carrying out the method according to the invention, with a nozzle area having at least one constriction area, is characterized in that the local area of the addition of the with the Additive-laden additional air flow is formed at the beginning of the narrowing area of the nozzle area. The addition is preferably carried out with the Additive-laden additional air flow through a slot which forms an angle of 45 ° with the axis of the nozzle area and is at a distance one quarter of the total length of the throat area from the entry end of the throat area.

In the following the invention is based on only one embodiment illustrative drawing explained again; the single figure shows, partially in a longitudinal section, a preferred embodiment of a blasting device for the method according to the invention.

The blasting device is a granular through a feed line 1 by means of flight conveyance Blasting medium 2 is supplied in a flow of support air, - the blasting device having a nozzle area 3; the direction of movement of the abrasive 2

is indicated by an arrow 4. The nozzle area 3 of the blasting device is made essentially from an elongated, approximately 75 cm long narrowing area 5 and an adjoining widening area 6 which is approximately two and a half times the length of the narrowing area 5; the narrowing area 5 and the widening area 6 are conical, they go in the area of the smallest cross section of the nozzle area 3, the nozzle constriction 7, into each other over.

In the case of the blasting device shown, the static pressure of the blasting agent is used 2 conveying air flow in the constriction area 5 of the nozzle area converted into kinetic energy; the accelerated air flow breaks that Blasting agent 2 with, so that the blasting agent 2 in the narrowing area 5 of the nozzle area 3 is accelerated.

According to the invention, in the initial area of the through the narrowing area 5 of the The acceleration section formed by the nozzle area 3 is added an additional air flow to the carrying air flow loaded with the blasting agent 2 via a slot 8, which is loaded with a liquid additive, in particular water. The loaded additional air flow is via a connection piece 9 and one - not - Feed line fed under pressure into an annular chamber 10, from where it is at an angle of about 45 ° to the direction of flight of the blasting medium through the slot 8 into the carrying air flow loaded with the blasting medium 2 is injected. In the injection area the dynamic pressure of the additional air flow is about twice as high as the dynamic pressure of the supporting air flow, so that the additional air flow can completely penetrate the air flow. This achieves that the blasting agent 2 can be wetted with the liquid additive uniformly and in doses.

In the exemplary embodiment shown, the local area of the addition is located of the additional air flow in the supporting air flow at about a quarter of the total length the throat area 5 of the nozzle area 3; the blasting agent 2 has thus only experienced about a quarter of the acceleration that it has in total the way to the nozzle constriction 7 of the nozzle area 3 experiences.

Claims (8)

Patent claims: Ly method for compressed air blasting, whereby a granular blasting agent in a Carrying air flow introduced and promoted by the carrying air flow, accelerated and is blown against a surface to be treated and the laden carrier air flow with a preferably liquid, preferably the Additive wetting abrasive, especially water, with adener additional air flow is added, in particular is injected into the carrying air flow loaded with the blasting agent, characterized in that that the addition of the additional air stream loaded with the additive in takes place in a local area of the laden air flow in which the speed and the acceleration of the abrasive is low. 2. The method according to claim 1, characterized in that the addition of the with the additive-laden additional air flow takes place at the beginning of the acceleration path of the blasting agent. 3. The method according to claim 1 or 2, characterized in that the additional air flow is injected into the support air stream at an angle of 20 ° to 70 °, preferably 45 °. 4. The method according to any one of claims 1 to 3, characterized in that the blasting media is given its own rotation in the injection area. 5. The method according to any one of claims 1 to 4, characterized in that a rotary movement of the blasting media in the injection area relative to the direction of flow of the air flow, in particular a helical rotary movement, is given. 6. The method according to any one of claims 1 to 5, characterized in that the additional air flow is injected into the support air flow at a pressure which is higher in the injection area than the pressure of the support air flow. 7. Blasting device for performing the method according to one of claims 1 to 6 with a nozzle area having at least one constriction area, characterized in that the local area of the addition of the with the additive loaded additional air flow is formed at the beginning of the constriction area (5) of the nozzle area (3). 8. beam device according to claim 7, characterized in that the addition of the with the additive loaded additional air flow takes place via a slot (8) which forms an angle of 45 ° with the axis of the nozzle area (3) and is at a distance of a quarter of the total length of the constriction region (5) from the entry end of the constriction region (5).