Abstract:
A nozzle structure for a paint spray gun, is comprised of a central outlet for paint, an annular slot surrounding the central outlet, the annular slot being connected inside the nozzle structure via an annular duct to a number of virtually axially parallel bores, the bores being situated on at least one circle about a central axis of the nozzle structure, apparatus for providing,  compressed air via the bores for delivery to the annular duct, and an air reversing  deflection disk located inside the annular duct and opposite the bores.

Description:
FIELD OF THE INVENTION 
     The invention relates to a nozzle arrangement for a paint spray gun, as well as the paint spray gun. 
     BACKGROUND TO THE INVENTION 
     A nozzle arrangement for a paint spray gun is described in German Utility Model G 90 01 265.8. The nozzle arrangement described in that document has a central outlet for the paint which can be closed with an axially extending pin. The paint flows pressureless from a fluid container to this sealable outlet. The outlet is surrounded by an annular slot out of which a circular air jet of high velocity flows, which thereby sucks paint out of the outlet, atomizes it and carries it along, as a result of which a circular jet consisting of paint particles is formed. 
     Laterally of the jet direction, the nozzle arrangement has two protruding horns, horn air jets of which are directed diagonally and in the same direction to the direction of flow of and into the circular jet, which deformed it. To control the horn air, the nozzle arrangement has, on both sides of the outlet in the direction of the horns, two or more control bores through which air passes and impacts the horn air jets and thus controls them. 
     Both the annular slot and the control bores are supplied with air from the same air chamber, namely an annular duct inside the nozzle arrangement. This annular duct is supplied with compressed air from supply bores which are located in a paint nozzle and the axes of which are arranged parallel and equidistant on a circle around the axis of the nozzle arrangement. 
     A disadvantage of the arrangement described is that the air does not flow uniformly into the annular slot via the supply bores arranged about the periphery inside the nozzle arrangement, as a result of which the air/paint mixture is not distributed as uniformly as possible in the circular jet. If the air pressure were measured along the periphery of the annular slot, then an almost sinusoidal modulation would result, whereby peaks occur in the angular area of the annular slot, in which the bores are also located, and minimums in between. 
     In addition, this arrangement has the disadvantage that the air from the supply bores reaches directly into the control bores for the horn air, depending on the angular position of the paint nozzle having the bores relative to the housing or air cap of the paint spray gun, when the supply bores are about colinear with these control bores and, as a result, the horn air is affected too greatly in an undesirable manner, which in turn changes the jet pattern in an undesirable manner. The spray result thus depends on the relative position of the air cap having the horns and control bores relative to the paint nozzle which has the supply bores. However, the position of the paint nozzle screwed into the housing of the paint spray gun is determined by the starting cut of its thread and thus a great extent accidental, so that some of the guns produced exhibit undesirable paint coat properties. 
     SUMMARY OF THE INVENTION 
     Thus, it is an object of the invention to provide a nozzle arrangement such that the annular air jet flows out as homogeneously as possible and accidental losses of quality are avoided during production. 
     In accordance with an embodiment of the invention a nozzle structure for a paint spray gun is comprised of a central outlet for paint, an annular slot surrounding the central outlet, the annular slot being connected inside the nozzle structure via an annular duct to a number of virtually axially parallel bores, the bores being situated on at least one circle about a central axis of the nozzle structure, apparatus for providing compressed air via the bores for delivery to the annular duct, and an air reversing  deflection disk located inside the annular duct and opposite the bores. 
    
    
     
       BRIEF INTRODUCTION TO THE DRAWINGS 
       An embodiment of the invention shall be described in greater detail with reference to the accompanying drawings, in which: 
         FIG. 1  is a cross-section through a paint spray gun, and 
         FIG. 2  is the nozzle arrangement used in the paint spray gun of  FIG. 1 , in section and partial cross-section. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The paint spray gun shown in the Figure is comprised essentially of a housing  30  which includes an upper part with a suspension hook and a handle  45 . A compressed-air supply conduit is attached to the underside of the handle  45 , an air choke  40  can be built in to decrease the pressure when the air enters, primarily in low-pressure guns; a fluid container for the paint is mounted on the top at a connection  46 . The compressed air (via a valve arrangement  32 ) and the outlet  3  (via a pin control device  33 ) are simultaneously released for the paint by means of an operating lever  31 . The paint flows from the fluid container (not shown), without pressure support, to the outlet  3  and passes out there when the pin  7  is pulled back. Compressed air flows simultaneously via a conduit system to the annular slot  5  which surrounds the outlet  3  and produces a vacuum directly at the outlet  3 . This vacuum sucks paint out of the outlet  3 , which is then atomized and carried along due to the quick-flowing air while forming a circular jet. The circular jet is pressed together by two horn air jets which pass out of the horns  21  forming a part of the nozzle arrangement  1 , in such a way that the circular jet is deformed into a flat jet. The air flow from the outlet holes  20  of the horns  21  is, in turn, affected by control bores  22  which are not provided with reference numbers in FIG.  1 . 
     To describe the nozzle arrangement  1  in greater detail, reference is made to  FIG. 2  below, in which axis  4  refers to the central axis of the nozzle arrangement, in which the pin  7  is also located and the direction of the flow of the main jet direction of the air/paint mixture passing out of the nozzle, as shown by arrow  12 . 
     The nozzle arrangement  1  shown in  FIG. 2  is comprised of paint nozzle  11 , which is screwed into a nozzle insert  10  (see  FIG. 1 ) of the paint spray gun  2  via an external thread  34  and which contains axially parallel air bores  18 . The paint nozzle  11  is surrounded by an air cap  16  which is screwed together with an external thread of the nozzle insert  10  with aid of a cap nut (not shown). 
     A middle section  35  of a larger diameter adjoins the external thread  34  of the paint nozzle  11  for screwing into the nozzle insert  10 , the middle section being hollow on the inside to admit the pin  7  and having an annular recess  47  on its rear facing the external thread  34 . Six axially parallel, identical bores  8 , arranged on a circle about the axis  4 , extend from this recess at a distance of 60° through the middle section  35  of the paint nozzle  11 . Finally, the paint nozzle  11  also has a front area  13  which extends from the outlet of the bores  8  to the front end of the paint nozzle  11 . This front area is comprised of a cylindrical part  36  whose diameter is small enough to keep the front end of the bores  8  clear. A further, disk-shaped cylindrical area of a larger diameter, which is relatively thin and is called an air reversing  deflection disk  9  below, adjoins this cylindrical area  36 . The diameter of the air reversing  deflection disk  9  is measured in such a way that, seen from the front, the bores  8  are completely covered. The furthermost front area of the paint nozzle  11  finally divides into a conical taper  23  at a first angle of about 30° to the axis  4 , a conical taper  24  adjacent thereto at a second, smaller angle and a cylindrical end area  25  adjacent thereto. 
     The air cap  16  surrounding the paint nozzle  11  when assembled is essentially symmetric to axis  4  on the inside. However, it has two horns  21  which are diametrically opposite one another and protrude beyond the annular slot  5  and outlet  3  in the direction of flow  12 . Two supply bores  19  extend from the rear of the air cap  16  to outlet holes  20  in the horns  21 , whereby each horn  21  has two holes  20 . Holes  20  are directed in such a way that they point to the axis  4  in the direction of flow  12  toward the annular slot  5 , that is, they can affect the air which has already passed out of the annular slot  5 . 
     The air cap  16  has a middle region which ends at the annular slot  5 . This middle region is passed through by four control bores  22  which are arranged on a line between the two horns  21 , that is, their air flow can again affect the horn air coming out of the outlet holes  20  of horns  21 . In the region of the inside control bores  22 , the inside wall of air cap  16  (which will be described later as outside wall  15  of the annular duct  6 ) curves continuously until it is parallel to axis  4 . Thus, there is no sharp transition here. 
     The assembled arrangement is comprised of paint nozzle  11  and air cap  16 , as shown in  FIG. 2 , and forms an annular duct  6  between the outside of the front area  13  (with  36 ) of the paint nozzle  11  and the inside of the air cap  16 . This annular duct  6  begins at the end of bores  8  and extends past the air reversing disk  9  to the annular slot  5 . To the outside, it is only opened by the control bores  22 . The outside wall  15  of the annular duct  6  tapers from the bores  8  to the annular slot  5 , at first continuously beyond the area of the air reversing disk  9 . A discontinuous jump then takes place on a plane annular surface  17 , which is directed essentially at right angles to the axis  4 . The outside wall  15  then tapers continuously again and changes in the area of the middle, that is of the annular slot  5 , continuously into a run parallel to the axis  4 , without a sharp bend taking place. 
     The inside wall  14 , formed by the paint nozzle  11 , with which the air reversing  deflection disk  9  can be made in one piece, also tapers adjacent to the air reversing  deflection  disk  9 , namely, as described above, at two different angles (areas  23  and  24 ) and then runs cylindrically (area  25 ). The innermost area of the air cap  16  thus forms the annular slot  5  with the cylindrical area  25  at the front end of the paint nozzle  11 . 
     The nozzle arrangement of the invention functions as follows after it has been attached to a paint spray gun. 
     By actuating the operating lever  31 , the pin  7  is pulled back opposite to the direction of flow  12  and, at the same time, the nozzle insert  10  is acted upon by two compressed air flows, which can be controlled separately on the paint spray gun. The outer compressed air flow reaches the outlet holes  20  via bores  18  in the nozzle insert  10  and the two supply bores  19  in the horns  21  of the air cap  16 . The outlet holes are directed downward or upward to the extension of the axis  4  in direction of flow  12 . The inner compressed air flow reaches the six bores  8  inside the paint nozzle  11  in the annular duct  6 . This compressed air flow hits the air reversing  deflection plate  9 , which completely covers bores  8 , at a high speed. Thus, a very turbulent flow, which also has considerable tangential components and distributes the compressed air in peripheral direction, results between the outlet of bores  8  and the air reversing  deflection plate  9 . The compressed air then flows through the narrow area of the annular duct  6  past the air reversing  deflection disk  9  and hits the plane annular surface  17 . A relatively strong turbulence results, in turn, due to the sudden change in direction and thus a further homogenization of the pressure ratios. 
     Finally, the compressed air passes through the rest of the annular duct  6  which continues to taper more and more and then has no more corners or edges acting as a flow reverser  deflector, but is kept as smooth and continuous as possible in order to attain a certain laminating of the flow. The air flow, almost completely homogenized in this way, passes out of the annular slot  5 , sucks the paint out of the outlet  3  in a known manner, atomizes it and carries it along while forming a circular jet. 
     The flow velocity is increased by the air duct  6  tapering in the direction of the annular slot  5 , that is, an optimum conversion of the fall in pressure takes place from the air duct  6  to the ambient pressure in velocity. 
     The circular jet thus formed is affected by the horn air from the outlet holes  20 , also in a known manner. The influence of the horn air takes place again in a known manner through the control bores  22 , however, significantly more homogeneously, more reliably and more uniformly than with the known nozzle arrangements. This is due to the fact that a straight alignment of the control bores  22  with bores  8  is no longer possible, because the air reversing  deflection plate  9  is located between them. Thus, in the nozzle arrangement of the invention, it is inconsequential what the relative position of paint nozzle  11  and air cap  16  is, since the air passing out of bores  8  is always prevented, with certainty, from flowing directly against the control bores  22  by means of the air reversing  deflection disk  9 . Due to the fact that uniform spray jet geometries result, a spray gun or nozzle arrangement of this type can also be made more quickly and with less expense. 
     The nozzle arrangement described can be used both in high-pressure and low-pressure paint spray guns. However, it does have special advantages in modern low-pressure guns since these react more sensitively to variations in pressure.