EP0044842A1 - Powder spraying device provided with a rinsing device. - Google Patents

Abstract

A cylindrical rod (3) movable longitudinally is disposed centrally with respect to the spray nozzle (2) of a powder spray gun (1). At its free end is a conical deflector (5) whose lateral surface (9) forms an acute edge (11) with the front face (10) concave conical. In the central exhaust channel (12) of the deflector (5) is provided a flushing nozzle having an approximately radial outlet orifice for the flushing air supplied by a source of pressurized air (19). The rinsing nozzle consists of a mushroom-shaped head (14) forming a deflector body placed very close to the end of the exhaust channel (12). This nozzle can also be produced in the form of a rotation nozzle using a sharp annular edge and a swirl chamber or a helical guide rib. The rinsing air flows continuously along the front face (10) and thus prevents agglomeration of the powder at this location. A switch valve (18) controlled by a button (20) can automatically direct the exhaust channel to a source of extinguishing gas (21) which expels gas into the projection region where there is the greatest danger of inflammation.

Description

 Powder atomizer with rinsing device

The invention relates to a powder atomizer with a spray nozzle for spraying powder supplied in a conveying gas stream, with a baffle arranged in the spray direction in front of the spray nozzle, the front side of which facing the nozzle directs the sprayed powder particles radially outwards, and with a flushing device which Purging gas for cleaning powder particles adhering to the impact body can escape under pressure from the rear side of the impact cone facing away from the spray nozzle.

In powder atomizers of this type, a vacuum and a vortex are formed on the rear side of the impact body facing away from the spray nozzle. Admittedly, this has the consequence that parts of the externally flowing conveying air are drawn inwards again with individual powder particles. However, these powder particles are not completely passed on and form powder deposits on the rear side of the impact body. This is particularly troublesome because from time to time individual powder agglomerates detach from the impact body, strike the workpieces to be coated in a compact form and cause surface defects there.

In order to avoid such irregularities, it is known from DE-OS 2 509 851 to produce the entire impact body or parts thereof from porous material and to free the surface from the inside by supplying air • _j to keep deposits. Practice shows, however, that this method has considerable disadvantages. The usual porous plastic materials become brittle and burst particularly quickly under the influence of the ozone generated in the high-voltage field. The same materials are washed away relatively quickly by abrasive powder materials and then have to be replaced at corresponding costs. The use of porous ceramic materials avoids these disadvantages, but is particularly subject to another influence, as described below: Since the compressed air never uses the usual refrigeration dryer is completely water-free, the porous surface is stuck with the finest powder particles.

The invention is based on the Pu atomizer described at the outset and serves the task of improving the rinsing device in the simplest possible manner so that the rear side and edge of the impact body are reliably kept free of powder particles.

To achieve this object, a pronounced purging nozzle with an essentially radial exit plane of the purging gas is provided in the middle of the impact body along the rear side of the impact body.

Here, the disadvantages that arise when using porous materials are initially avoided. Instead of a light gas sprinkling, a distinctive flushing jet is guided along the back. In this way, the vacuum formed there cannot be completely filled, i.e. it is still sucked in from the outside inward, and usually a limited vortex is still formed, but the rear of the impact body is practically no longer directly affected by this phenomenon. It is therefore not possible for individual powder particles to adhere there, nor for flakes, incrustations or the like to form, which will later unintentionally reappear

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OM ^{V IP} could solve. This is also achieved without any special effort, since the impact body can be produced essentially in one piece from the conventional materials, in particular insulating plastic.

According to a preferred embodiment of the invention, the rear side of the impact body is formed concave, in particular conical, in the center of the flushing nozzle and delimited by a sharp ring edge. This does not necessarily have to be a conical surface with straight surface lines, but the cone can continue to be concave, that is to say the cone angle is larger in the middle than at the edge. This further facilitates the guidance of the flushing gas, which can then emerge more radially and may be deflected more towards the edge in the spray direction. The sharper the edge or the smaller the edge angle, the greater the entrainment effect from the purge air. ^'The greater the uniformity of the subsequent flow.

The tip angle of the rear side of the impact body in the immediate area of the flushing nozzle is expediently between 110 ° and 170 °, in particular between 130 ° and 150 °.

According to one embodiment of the invention, the flushing nozzle is designed as an annular gap nozzle with an essentially radial gas outlet. The flushing nozzle can have a central pin with a head which acts as a deflecting body and which is preferably tapered away from the nozzle.

According to another embodiment of the invention, the flushing nozzle is designed as a rotating nozzle with a rotating gas outlet. For example, it can have an inwardly directed annular cutting edge, which is preceded by an annular chamber and guide means for rotatingly guiding the purge gas into or into the annular chamber. The rotation effect can be by helical or spiral guide vanes or ribs or by just one only angled inlet hole can be achieved. When it emerges from the nozzle, the tangential and thus the radial speed component is then substantially greater than the axial one. The dedusting is favored _c supply it through the "Coanda effect", which states that egg once a surface-scale air jet at this Fl che along strokes and can not solve it. In addition, the adhesive effect on the concave or hollowed-out rear surface sought here is greater than on a flat or even convex surface.

However, the two nozzle shapes can also be combined in such a way that a rotating purge air stream is let out of an annular nozzle.

The impact body is preferably seated on the front end of a feed pipe, which is in particular guided lengthways through a spray gun and the rear end of which can be connected to a purge gas source. It is currently considered to be advantageous to allow the purge gas to flow out continuously, with a delivery pressure of 0.2 to 1.3 bar being sufficient, but it is also a periodic impulse initiation of the purge. gases conceivable, provided that this does not affect the spraying process itself.

The use of an inert gas such as halon as an extinguishing gas for fires in powder spraying is known per se. However, the gas is usually introduced into the wider area of the fire source through separate supply lines. Fires in powder spraying now proceed almost without exception from the straight-acting spray gun and develop downstream of the impact body, precisely where the flushing gas according to the invention is introduced in a relatively vigorous flow.

According to the invention, devices for introducing extinguishing gas are now on the way of the purge gas to the rear of the

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// ,. I Impact body provided, ie the extinguishing gas is directed to where the fire can start. It is understood that larger quantities of gas can then be supplied than in the normal rinsing, ie one will work with higher pressures of approximately 2 to 3 bar. In this case, a pressure-influenced movable valve element can also be provided, which automatically enlarges the smallest valve cross-section when extinguishing gas is supplied at a higher pressure.

A changeover switch for switching from a purge air source to an extinguishing gas source is then expediently provided in the purge gas duct. This changeover switch or such a changeover valve is expediently controlled automatically by a flue gas pushbutton in order to enable an immediate response.

The invention is shown in the drawing, for example. Show it

1 shows a schematic illustration of a powder atomizer according to the invention,

2 shows a section through a modified embodiment of an impact body used there and

3 shows a modification of the impact body from FIG. 2.

In the drawing, 1 denotes a powder spray gun, of which the design is essentially widely known and therefore need not be explained further. A conveying gas stream with finely divided spray powder is supplied to this pistol in a manner not shown further and is sprayed through a spray nozzle 2 to the right in the drawing. A tubular rod 3 is guided centrally to the spray nozzle through the whole powder gun, on the rear end of which there is a connecting sleeve 4 which also serves as a sliding handle. In this way, the distance a between the spray nozzle 2 and one Adjust the impact body 5, which sits on the front end of the tubular rod 3 by means of a counterbore and an annular seal 6.

This impact body 5 has a rotationally symmetrical front surface 7 which merges from a slim conical hub 8 over a central toroidal surface into a blunt conical surface 9 which has a sharp edge 11 and an angle of less than 10 ° with the conical back 10 of the impact body forms.

The back side 10 is here as a conical surface with a straight Man tellinie au _f leads, can also expediently et what bombig with slightly cupped edges configured wer¬ j edoch the.

Continuing with the hollow of the tubular rod 3, a central outlet channel 12 is provided in the impact body 5, in which a pin 13 is seated by means of radial webs, the mushroom head 14 of which is tapered in the direction of flow and an annular gap 15 with the inner edge of the conical rear side 10 forms, from which purge gas supplied under a pressure of 0.2 to 1.3 bar flows essentially radially in a fan-shaped manner along the rear face, in a radially fanned manner.

The fetder gas emerging from the spray nozzle 2 is deflected outward with the powder particles carried by it through the front side 7 of the impact body 5 and joins again more downstream in the direction of the spray axis downstream of the impact body 5. The flow tends to break off at the edge 11 to form a vortex braid, and a vacuum is built up just behind the impact body, which results in irregular inflows and causes powder particles which are swirled inward to adhere to the rear and later to uncontrollably settle to solve. ., The now introduced spray flow according to the arrows 16 prevents such a setting of a powder particle on this rear surface and especially on the edge 11. In the area of this relatively sharp edge

Now two nearly identical gas flows meet from the inside and outside, the outer strong

Conveying gas flow entrains the inner, weaker purge gas flow and thus increases the purge effect.

The rear connecting sleeve 4 is connected via a hose 0 17 to an electrically controllable changeover valve 18, which normally maintains a flow connection from a compressed air source 19 to the hose 17. The changeover valve 18 is however controlled by a smoke gas sensor 20 and switches immediately to a connection of an extinguishing gas source 21 to the hose 17 as soon as traces of smoke gas are found in the room. Extinguishing gas, as it is commercially available under the name Halon (fluorinated halogenated hydrocarbon), is then led along the purge gas path directly to the impact body, exactly where there may be an ignition.

In order to further improve the extinguishing gas effect, the pin 13 could also be slidably mounted against spring force in order to enlarge the width of the annular gap 15 as a result of the higher supply pressure.

In the impact cone 51 shown in FIG. 2, which in principle has the same outer shape as the impact body 5 according to FIG. 1, a rotationally symmetrical swirl chamber 22 is provided on the inside, which is located in a circular nozzle opening 23 within an annular edge 24 with the Back 10 is connected and the purge air is supplied on a screw path through a tangential oblique bore 25 from the central bore 26.

When the purging gas is introduced into the swirl chamber, it is rotated centrically to the purging axis and enters along the ring edge 24 primarily with a tangential direction. In any case, the flow takes place in a widening vortex according to the arrows Ϊ6 on the back 10, whereby an increased adhesive effect e is aimed.

Instead of the tangential introduction with a relatively coarse screw pitch, guide ribs provided in the center of the chamber can also be provided in screw or spiral form.

Such an embodiment is illustrated by FIG. 3. The impact body 52, which otherwise corresponds to the impact body 51 a. FIG. 2 has an elongated cylinder chamber 29 with respect to the swirl chamber 2, which is connected to the bore of the raw rod 3 with a central inflow channel 33. In the center of the cylinder chamber 29, a i ^• sits substantially cylindrical guide body 27 which alternate each other on its outside helicoidal guiding ribs 28 and helical grooves 30 aufweist.und a Vor¬ chamber 31 from the downstream swirl chamber 22 a tre

The S _j oll air flowing from the tubular rod 3, essentially laminar, into the Vo chamber 31 is initially decelerated there and introduced evenly into the screw grooves 30. From there, it is introduced into the swirl chamber 22 a in a rotational flow about the body axis, where it is supplied to the nozzle opening 23 in substantially the same manner as in FIG. 2.

Claims

Expectations

1. Powder atomizer with a spray nozzle for spraying powder supplied in a conveying gas stream, with a baffle arranged in the spray direction in front of the spray nozzle, the front side of which faces the nozzle and directs the sprayed powder particles radially outwards, and with a flushing device for flushing gas Cleaning of powder particles adhering to the impact body under pressure can exit from the rear side of the impact body facing away from the spray nozzle, characterized in that in the center of the impact body (5) a pronounced flushing nozzle (12-14) with an essentially radial exit plane of the flushing gas ent long the back (10) of the impact body is provided.

2. Powder atomizer according to claim 1, characterized gekennzeich¬ net that the back (10) of the impact body (5) centrically to the flushing nozzle (12 - 14) is concave, in particular conical and is bordered by a sharp ring edge (11).

3. Powder atomizer according to claim 2, characterized in that the seat angle of the rear side (10) of the impact body (5) in the immediate area of the flushing nozzle (12-14) is between 110 ° and 170 °, in particular between 130 ° and 150 °.

4. Powder atomizer according to claim 1, 2 or 3, characterized in that the flushing nozzle (12 - 14) is designed as an annular gap nozzle with a substantially radial gas outlet (FIG. 1).

5. Powder atomizer according to claim 4, characterized in that the rinsing nozzle (12-14) has a central pin (13) with a head (14) acting as a deflector, which is preferably tapered away from the nozzle.

6. Powder atomizer according to claim 1, 2 or 3, characterized in that the flushing nozzle is designed as a rotating nozzle (22 - with rotating gas outlet (Fig. 2).

7. Powder atomizer according to claim 6, characterized in that the flushing nozzle (22-25) has an inwardly directed ring cutter (24) which has a swirl chamber (22) guide means (25) for rotatingly guiding the flushing gas into or in the swirl chamber are upstream.

8. Powder atomizer according to claim 7, characterized in that the guide means have a rotationally symmetrical guide body (27) arranged in or in front of the whirl chamber (22a), which is provided at least on its outside with helical guide ribs (28).

9. Powder atomizer according to one of claims 1 to 8, characterized in that the ^' impact body (5) sits on the front end of a feed tube rod (3), which in particular is longitudinally adjustable through a spray gun (1) and the rear end of which can be connected to a purge gas source (19).

10. Powder atomizer with a spray nozzle for spraying vσi in a conveying gas stream, with a baffle arranged in the direction of spray in front of the nozzle, the front of which faces the nozzle and directs the sprayed powder particles radially outwards, and with a feed device for flushing gas that is used to clean off powder particles adhering to the impact body under pressure from the back of the impact cone facing away from the spray nozzle, in particular according to one of claims 1 to 8, characterized by devices (18, 20, 21) for introducing extinguishing gas on the way of the purge gas to the rear ( 1 of the impact body (5).

11. Powder atomizer according to claim 10, characterized gekenn¬ characterized in that in the purge gas guide a switch (18) for switching from a purge air source (19) to e - 11 - Extinguishing gas source (21) is provided.

12. Powder atomizer according to claim 11, characterized gekenn¬ characterized in that the switch (18) by a flue gas c button (20) is automatically controllable.