DE9001265U1 - Nozzle head for a paint spray gun - Google Patents

Description

Description

The innovation relates to a nozzle head for a paint spray gun according to the preamble of claim 1.

Such nozzle heads are, for example, the subject of DE-B 24 22 597 and GB 701 280. The horn air jets emerging from the horn air nozzles have the task of deforming the central ring air jet 2u of a flat jet.

If paints with the higher paint viscosities that are common today are processed with such nozzle heads, it can be seen that paint clumps settle on the horns, particularly in the area of the horn air nozzles. This addition of leak droplets is harmful , as it impairs the horn air jets.

In the known nozzle heads mentioned at the beginning, the round jet is swirled more or less ^after it exits the paint and ring nozzle, depending on the spray viscosity of the paint. If the horn air jets hit this ^swirled round jet, it is slowed down, with paint droplets accumulating in the angular area between the horn air jets and the round jet, i.e. in the area before the jets meet. The horn and ring nozzle jets are free air jets that entrain part of the still ambient air, causing the ambient pressure to drop. This drop in ambient pressure in turn leads to a backflow movement along these jets in the direction of the nozzles, with the aforementioned paint droplets being transported from the aforementioned area in the direction of the nozzles and settling there.

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From DE-A 14 25 890 a nozzle head is known in which the horn air nozzles have nozzle boundary surfaces which taper in the direction of the mouths of the horn air nozzles. In this case, however, the horn air jets are directed obliquely against the outflow direction onto the round jet, so that different conditions exist than in a nozzle head in which the horn air jets are directed obliquely in the outflow direction onto the round jet.

These different conditions become clear when one takes into account the flow conditions of the known nozzle heads, in which the horn air jets are directed obliquely in the outflow direction towards the round jet.

Since in the subject matter of DE-A 14 25 890 the horn air jets are directed at an angle and in the opposite direction to the outflow direction towards the round jet, a swirling round jet causes paint droplets to be conveyed back towards the air cap, where they settle in the area of the air ring nozzle. For this reason, only nozzle heads are used in which the horn air jets are directed at an angle and in the same direction as the outflow direction towards the round jet.

The task is to improve the nozzle head in such a way that fogging with paint droplets in the area of the nozzles and in particular in the area of the air nozzles is largely avoided.

This problem is solved with the characterizing features of claim 1. Advantageous embodiments can be found in the subclaims.

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Embodiments of the invention are explained in more detail below and in the drawings. They show:

Figure 1: a section through a first embodiment of a nozzle head;

Figure 2: a partially sectioned side view of this nozzle head in a position rotated by 90° to Figure 1;

Figure 3: a plan view of a horn of this nozzle head in arrow direction III according to Figure 1;

Figure 4: a top view of this nozzle head; Figure 5: a section corresponding to Figure 1

through the air cap of this nozzle head and

Figure 6

to 12: Sections through a horn in seven other variants.

Nozzle heads of the type discussed here have a paint channel 1 that opens into a central paint nozzle 2, whereby the connection between the paint channel 1 and the paint nozzle 2 is controlled by a needle 3. The paint nozzle 2 is surrounded by an air ring nozzle 4, to which air is supplied via channels 5. An air cap 7 is placed on the paint nozzle body 6, the central bore 8 of which delimits the air ring nozzle 4 on the outside. This air cap 7 has two obliquely running nozzle bores 9 from which fan-out air jets emerge. The air cap 7 is provided with two horns 10.

each having a nozzle bore 11 which is supplied with compressed air via further air bores 12.

The nozzle bores 9 are arranged between the bore 8 and the horns 10 and point obliquely in the direction of the ring air jet emerging from the ring nozzle 4. The air cap 7 is flat in its front area 30, but has an annular elevation 31 that protrudes above this flat area 30, which surrounds the bore 6 and consists of an annular surface and a conical surface that adjoins it to the outside.

The high-energy ring air jet exiting the ring nozzle 4 sucks the paint out of the paint nozzle 2, forming a round jet that flows in the direction of the arrow 13. Horn air jets exit the two nozzle holes 11, which are directed at the round jet and run at an angle and in the same direction as the outflow direction 13 of the round jet.

The horn air nozzles 15 according to Figures 1 to 5 have a nozzle limiting surface 17 around the nozzle opening 16, which consists of a narrow ring surface 18 and the surface of a conical shell 19 that tapers in the direction of the opening 16. The ring surface 18, which runs at right angles to the nozzle axis, should be as narrow as possible. For manufacturing reasons, a width s of about 1 mm is appropriate. In the embodiment according to Figure 6, this ring surface 18 is practically eliminated. The angle of the conical shell is preferably a maximum of 180, as shown in Figure 5.

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The conical surface 19 ensures that the ambient air entrained by the horn air jet I flows tangentially into the area of the nozzle opening 16, as indicated by the arrows 20 in Figure 6. This undisturbed tangential flow of the ambient air into the horn air jet I prevents paint droplets from settling on the horn air nozzle 15. Instead, these paint droplets are conveyed back to the round jet by the flow in the direction of the arrow 20 and are carried along by it. In order to enable this tangential flow, the nozzle boundary surface 17 protrudes above the surface 21 of the horn.

According to Figure 7, the nozzle boundary surface 17 is formed by a conical surface 19, which is smaller in comparison to the first embodiment.

In the embodiment according to Figure 8, a pipe section 22 is inserted into the nozzle bore 11, which protrudes beyond the surface 21 of the horn and which is conical on the outside in the area of the mouth 16.

In the embodiment example according to Figure 9, a curved tube 24 is inserted into the front side 23 of the air cap 7, the outer surface of which is also conical in the area of the mouth. This tube 24 therefore forms both the horn and the horn air nozzle.

In the embodiment according to Figure 10, a ball 25 is inserted into the nozzle bore 11, which has a through-bore 26 and which projects approximately halfway over the surface 21 of the horn.

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According to Figure 11, the nozzle boundary surface 17 is formed by a circular cylinder 27, the height of which is preferably between 0.4 mm and 1.0 mm,

In all embodiments cn it can be realized that a recess 28 is provided to protect the nozzle orifice 16, which in the embodiment shown is designed as a cylinder recess.

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This prevents paint droplets from settling on the horns in the area of the nozzle boundary surface 17, so that the exit of the horn air jets is not impaired.

Settling of paint droplets is also avoided in the area of the ring nozzle 4, since the ambient air entrained by the compressed air flowing out of the ring nozzle 4, which flows over the surface 30 and can flow approximately tangentially into the circular jet due to the elevation 31.

The fanned air jets emerging from the nozzles 9, which have a lower flow speed than the round jet due to their small nozzle diameter, slow down the horn air jets and fan them out. Because their flow direction is directed towards the previously explained accumulation area for paint droplets between the round and horn jet air, the inclination and thus the backflow of paint droplets along the round jet is significantly reduced. All of these measures prevent the deposition of paint droplets on the surface.

Claims (13)

■ « t ■ * ■ «a « ■ claims - ; 1. Nozzle head for a paint spray gun with a central paint nozzle, an air ring nozzle surrounding this paint nozzle, from which a ring air jet emerges with high energy, which sucks paint out of the paint nozzle and forms a round jet, and with at least two horn air nozzles on at least two lateral horns protruding in the jet direction, the horn air jets of which are directed obliquely and in the same direction as the outflow direction onto the round jet and deform it, characterized in that the nozzle boundary surface (17) of each horn air nozzle (15) projects beyond the surface (21) of the horn (10) and essentially enables an essentially tangential, undisturbed inflow (20) of the ambient air from all sides into the horn air jet emerging from the horn air nozzle (15). 2. Nozzle head according to claim 1, characterized in that the front region (30) of the air cap (7) is flat and has a raised portion (31) which surrounds the bore (8) which delimits the air ring nozzle (4). 3. Nozzle head according to claim 2, characterized in that the elevation (31) consists of an annular surface and an outwardly adjoining conical surface. 4. Nozzle head according to one of claims 1 to 3, characterized in that between the air ring nozzle (4) and the horns (10) at least one air nozzle (9) is provided, which run in a wedge shape towards each other as seen in the jet direction (13). &bull; ■ · ■-7 years? if« ■ · &igr; &bull; I HII · · ·· 5. Nozzle head according to one of claims 1 to 4, characterized in that the nozzle boundary surface (17) tapers in the direction of the mouth (16) of the horn air nozzle (15). "Nozzle head according to one of claims 1 to 5, characterized in that the outer boundary surface <17> is designed as a surface of a regulating element (19). 7. Nozzle head according to claim 6, characterized in that the angle of the conical shell (19) is a maximum of 180°. 8. Nozzle head according to claim 6 or 7, characterized in that an annular surface (18) running perpendicular to the nozzle axis is arranged around the mouth (16) of the horn air nozzle (15), the width of which is approximately 1 mm. 9. Nozzle head according to one of claims 1 to 5, characterized in that the horn air nozzle (15) is formed by a pipe section (22) with a conical mouth inserted into the horn (10). 10. Nozzle head according to one of claims 1 to 5, characterized in that the horn (10) and the horn air nozzle (15) are formed by a bent tube (24) with a conical mouth inserted into the air cap (7). ■ · ■ ■ · * 11. Nozzle head according to one of claims 1 to 5, characterized in that the horn air nozzle (15) is formed by a ball (25) inserted into the horn (10) with a through hole (26). 12. Nozzle head according to one of claims 1 to 5. »characterized in that the nozzle boundary surface (17) consists of a circular cylinder (27) whose height is at least 0.4 mm« 13. Nozzle head according to one of claims 1 to 12, characterized in that the openings C16> of the air nozzles (15> ) are provided with a countersink (28).