SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a coating is spiral-flow type nozzle for airless spraying realizes that coating from the even blowout all around of blowout nozzle to air in the coating appears, realizes airless spraying.
The utility model provides a coating is swirl nozzle for airless spraying, including the feeding section, straight section of thick bamboo, shrink section and blowout nozzle, straight section of thick bamboo cavity is cylindric structure, the upper end of straight section of thick bamboo lateral wall sets up the feeding section, the feeding section cavity is cylindric structure, straight section of thick bamboo cavity and feeding section cavity intercommunication, the internal diameter of feeding section cavity is less than the internal diameter of straight section of thick bamboo cavity, the feeding section cavity is arranged along the tangential of straight section of thick bamboo cavity, the lower extreme of straight section of thick bamboo sets up the shrink section, shrink section cavity from the last shrink gradually downwards, straight section of thick bamboo cavity and shrink section cavity intercommunication, straight section of thick bamboo cavity lower extreme opening aligns with blowout nozzle cavity upper end opening, the axis of straight section of thick bamboo coincides with the axis of shrink section, the lower extreme of shrink section sets up the blowout nozzle, shrink section cavity and blowout nozzle intercommunication, shrink section cavity lower extreme opening aligns with blowout nozzle upper end opening.
Further, a plurality of protrusions are arranged on the inner wall of the spraying nozzle in a surrounding mode at equal intervals.
Furthermore, two sides of the protrusion are symmetrical cambered surfaces.
Further, the cambered surface is an arc surface which is concave towards the protrusion.
Furthermore, the bulges are connected into a whole, and are arranged in central symmetry.
Furthermore, the number of the bulges is five, and the section of the ejection nozzle is in a quincuncial shape.
Further, the contraction section cavity is of an inverted frustum-shaped structure.
Furthermore, the lower end of the straight cylinder section is provided with an upper assembling lug, the upper end of the contraction section is provided with a lower assembling lug, and the upper assembling lug and the lower assembling lug are assembled into a whole through a bolt.
Furthermore, the upper assembling lug is annular and is arranged around the straight cylinder section; the lower assembling lugs are annular and are arranged around the periphery of the contraction section; the bolts are multiple and are arranged at equal intervals around the axis of the straight cylinder section.
Compared with the prior art, the utility model discloses a coating is swirl nozzle for airless spraying has following characteristics and advantage:
the spiral-flow type nozzle for airless spraying of the coating has simple structure, convenient assembly and lower cost;
the utility model discloses a coating is spiral-flow type nozzle for airless spraying, coating are after feed section, straight section of thick bamboo section and shrink section in proper order, and the air in the coating is appeared and is got into negative pressure zone and form the air column, and the air column gets into the blowout nozzle and puts the blowout from the central point of blowout nozzle, and coating gets into the blowout nozzle and from the blowout nozzle spout all around, and spun coating does not have the air doping, realizes airless spraying, is showing the atomization effect who improves the coating spraying, and the spraying area is big, and the spraying surface is even.
After reading the detailed description of the present invention in conjunction with the drawings, the features and advantages of the present invention will become more apparent.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.
In order to make the above objects, features and advantages of the present invention more obvious and understandable, the following spiral-flow type nozzle for airless spraying of coating of the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.
In the description of the present invention, it should be noted that the terms "upper", "lower", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.
As shown in fig. 1 and fig. 2, the present embodiment provides a swirl nozzle for airless spraying of paint, which comprises a feeding section 1, a straight section 2, a contracting section 3 and a nozzle 4. The feeding section 1 and the straight cylinder section 2 are integrally formed, and the contraction section 3 and the spray nozzle 4 are integrally formed.
The cavity of the straight cylinder section 2 is of a cylindrical structure, the upper end of the side wall of the straight cylinder section 2 is provided with the feeding section 1, the cavity of the feeding section 1 is of a cylindrical structure, and the cavity of the straight cylinder section 2 is communicated with the cavity of the feeding section 1. The inner diameter of the cavity of the feeding section 1 is smaller than that of the cavity of the straight cylinder section 2, and the cavity of the feeding section 1 is arranged along the tangential direction of the cavity of the straight cylinder section 2. The coating enters the cavity of the straight cylinder section 2 from the feeding section 1 along the tangential direction of the cavity of the straight cylinder section 2 and continues to rotate at the upper part in the cavity of the straight cylinder section 2, so that the components of the coating are preliminarily mixed.
The lower end of the straight cylinder section 2 is provided with an upper assembling lug, the upper end of the contraction section 3 is provided with a lower assembling lug, and the upper assembling lug and the lower assembling lug are assembled into a whole through a bolt 8 so that the lower end of the straight cylinder section 2 is assembled with the contraction section 3. Wherein, the upper assembling lug is annular and is arranged around the straight cylinder section 2; the lower assembling lugs are annular and are arranged around the contraction section 3; the bolts 8 are multiple, and the multiple bolts 8 are arranged at equal intervals around the axis of the straight cylinder section. The straight cylinder section 2 and the contraction section 3 are assembled through the upper assembly lug, the lower assembly lug and the bolt 8, so that the nozzle is convenient to disassemble, assemble and maintain.
The cavity internal diameter of shrink section 3 is from the top down and is reduced gradually, and the cavity of shrink section 3 in this embodiment is back frustum-shaped structure. The cavity of the straight cylinder section 2 is communicated with the cavity of the contraction section 3. The lower end opening of the cavity of the straight cylinder section 2 is aligned with the upper end opening of the cavity of the contraction section 3, and the axis of the straight cylinder section 2 is coincided with the axis of the contraction section 3. Under the action of gravity and centrifugal force, the coating spirally moves downwards in the cavity of the straight cylinder section 2 to the contraction section 3, and the rotation speed of the coating is increased in the cavity of the contraction section 3, so that the secondary mixing of the components of the coating is realized.
The coating rotates along the inner walls of the cavities of the straight cylinder section 2 and the contraction section 3 to form an outer spiral flow 5 in a spiral downward direction, an inner spiral flow 6 in a spiral upward direction is formed at the axial line of the straight cylinder section 2 and the axial line of the contraction section 3 after the outer spiral flow 5 runs to the contraction section 3, a columnar negative pressure area is formed inside the inner spiral flow 6, and air in the coating can be separated out and enter the negative pressure area to form an air column 9.
The lower extreme of shrink section 3 sets up blowout nozzle 4, and the cavity and the blowout nozzle 4 intercommunication of shrink section 3, the cavity lower extreme opening of shrink section 3 and 4 upper end openings of blowout nozzle align.
The paint continues to enter the nozzle 4 along the outer swirl flow 5 and is ejected from the periphery of the nozzle 4, and the air column 9 enters the nozzle 4 and is ejected from the center of the nozzle 4.
In this embodiment, a plurality of protrusions are circumferentially arranged on the inner wall of the ejection nozzle 4 at equal intervals. When the coating flows around the spraying nozzle 4, the coating is scattered by the bulges, so that the sprayed coating is more uniform. Preferably, the two sides of the bulge are symmetrical cambered surfaces, so that the bulge in the shape has a good effect of scattering the coating, and the spraying area is large; more preferably, the cambered surface is an arc surface which is concave towards the protrusion, so that the effect of scattering the paint and the spraying area are better. On the basis, the bulges are connected into a whole and are arranged in central symmetry, so that the bulges are convenient for machining.
In this embodiment, the number of the protrusions is five, and the cross section of the nozzle 4 is in a quincuncial shape, so that the optimal solution of this embodiment is that the effect of scattering the coating is the best, the sprayed coating is uniform, the spraying area is large, and the mechanical processing is convenient.
The embodiment also provides an airless paint spraying method, which is implemented by applying the spiral-flow type nozzle for airless paint spraying, and comprises the following steps:
step one, pressing the component A and the component B of the coating into a feeding section 1 by a pump at a set pressure, mixing air in the coating in the pressing process of the component A and the component B of the coating, enabling the coating to enter a cavity of a straight cylinder section 2 through the feeding section 1 along the tangential direction of the cavity of the straight cylinder section 2, and enabling the coating to rotate at the upper part in the cavity of the straight cylinder section 2 so as to enable the component A and the component B of the coating to be subjected to the action of a shearing force to realize primary mixing;
secondly, under the action of gravity and centrifugal force, the coating spirally moves downwards in the cavity of the straight cylinder section 2 to the contraction section 3, the shearing force borne by the coating is increased in the cavity of the contraction section 3, and the rotating speed (tangential speed) of the coating is increased more and more, so that the component A and the component B of the coating are secondarily mixed;
in the first step and the second step, the coating rotates along the inner walls of the cavities of the straight cylinder section 2 and the contraction section 3 to form a spiral downward outer rotational flow, the outer rotational flow forms a spiral upward inner rotational flow at the axial line of the straight cylinder section 2 and the axial line of the contraction section 3 after running to the contraction section 3, a columnar negative pressure area is formed inside the inner rotational flow, and air in the coating is separated out and enters the negative pressure area to form an air column 9;
and step three, the coating continues to enter the spraying nozzle 4 along the outer rotational flow and is sprayed out from the periphery of the spraying nozzle 4, and the air column 9 enters the spraying nozzle 4 and is sprayed out from the central position of the spraying nozzle 4 to be uniformly sprayed on the surface of the material 7 to be sprayed.
The paint airless spraying method of the embodiment applies the spiral-flow type nozzle for airless spraying of the paint of the embodiment, the paint sequentially passes through the feeding section 1, the straight cylinder section 2 and the contraction section 3, so that air in the paint is separated out and enters the negative pressure area to form the air column 9, the air column 9 enters the spray nozzle 4 and is sprayed out from the center of the spray nozzle 4, the paint enters the spray nozzle 4 and is sprayed out from the periphery of the spray nozzle 4, the sprayed paint is free of air doping, airless spraying is achieved, the atomization effect of paint spraying is remarkably improved, the spraying area is large, and the spraying surface is uniform.
Of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and the changes, modifications, additions or substitutions made by those skilled in the art within the scope of the present invention should also belong to the protection scope of the present invention.