1. Field of the Invention
The present invention relates to a spray gun for spraying paints and similar viscous media that can be propelled pneumatically, comprising a gun housing for accommodating the components of the spray gun that effect propulsion, mixture and/or metering, a handle projecting from the gun housing, and a reservoir tank removably attached to the gun housing for holding the medium to be processed, with the housing of the spray gun provided with an air guidance duct through which the compressed air responsible for atomization flows to an atomizer nozzle.
2. Description of the Prior Art
In disclosed spray guns of this type, the surfaces of the individual components that come into contact with the compressed air responsible for atomization have a smooth configuration so that the friction resistance is kept low. Although these embodiments have proven their effectiveness in practice, it is only possible to increase the atomizer performance by increasing the pumping pressure. Amongst other factors, this demands a considerable amount of construction complexity and involves a permanently increased power consumption, with the effect that the efficiency and economy of a spray gun are unfavorably influenced.
A spray gun of this type for atomizing fluids is disclosed in DE 10 2004 027 551 A1, wherein an atomizer nozzle is arranged in a sleeve. The handle projects from the sleeve. A reservoir tank is removably attached to the sleeve. The air flow required for atomization is generated by an air turbine driven by an electric motor. The components that come into contact with the air flow do not have a structured surface, so as to reduce the flow resistance.
The purpose of the present invention is therefore to create a spray gun using structural methods alone that enables the air speed to be increased and therefore allows an increase in the pumping rate of the medium to be transported. The constructional complexity required in order to achieve this should be kept small while retaining the full range of functions, and while allowing a significantly higher quantity of the medium to be transported with the same energy requirement, although at a higher speed.
In accordance with the present invention, this is achieved in a spray gun of the aforementioned type in which the surfaces of the air guidance duct and/or atomizer nozzle, and/or an air cap, which come into contact with the stream of compressed air, or are wetted, are provided wholly or in part, with a structured surface in the form of indentations and/or protrusions worked into the surfaces, either successively or with lateral spacings therebetween.
The projected surfaces of the indentations and/or protrusions can be circular, rectangular, oval, ellipsoid, lens-shaped or polygonal.
Regularly formed indentations and protrusions can be arranged, preferably with an even distribution, on the surfaces that come into contact with the flow of air. However, it is also possible for the surfaces that come into contact with the flow of air to have irregularly formed protrusions and indentations arranged unevenly thereon.
The indentations and/or protrusions can also be embodied as scales, preferably overlapping, arranged in the flow direction.
The indentations and/or protrusions are provided with a lateral extent of 1 to 10 mm and a maximum depth or height of 3 mm.
If the surfaces of a spray gun that come into direct contact with compressed air are configured in accordance with the present invention, it is possible to achieve a significant increase in the pumping speed for the same energy consumption as is required with conventional, smooth contact surfaces, with the effect that the transport rates can be significantly increased without needing to input additional energy. This is because the indentations and/or protrusions provided reduce the air resistance at the surfaces of the components. Depending on the type and arrangement of the indentations and/or protrusions, it is possible to achieve increases of up to 30% in the transport quantities. In this way, the transport quantity of a medium to be processed can be increased significantly without significant constructional complexity and, above all, without requiring the pump unit to draw additional power.
The drawings shows various sample embodiments of a spray gun configured in accordance with the present invention, which are explained in detail below. In the drawings,
d show various arrangements of indentations and/or protrusions as schematic views;
a and 5b show indentations and protrusions in sectional views;
The spray gun 1 shown in
The reservoir tank 5 in the illustrated embodiment is screwed into a projection 8 that is firmly connected to the gun housing 2 and has a duct 9 connected to the reservoir tank 5 and an annular chamber 10. The annular chamber 10 is created by a sleeve 12 into which a nozzle needle 13 is inserted. The nozzle needle 13 can be moved to the right, as show in
In order to increase the air speed in the gun housing 2, as well as between the atomizer nozzle 4 and an air cap 15 allocated to the nozzle 4, all of the surfaces of the spray gun 1 that come into contact with the flow of compressed air are wetted in an air guidance duct 21 provided in the gun housing 2, therefore its inner jacket surface 22, as well as the atomizer nozzle 4 and the air cap 15, as well as the ducts 16 (
a to 11 present individual schematic views of how the indentations 51 and/or protrusions 52 can be configured.
In accordance with
a and 5b show sectional views of the gun housing 2, thereby allowing the indentations 51 and protrusions 52 to be recognized as such.
In accordance with
The inner jacket surface 22 of the air guidance duct 21 of the spray gun 1 can, However, also be configured, as shown in
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Number | Date | Country | |
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20070241208 A1 | Oct 2007 | US |