WO2014173799A1 - Method and blasting nozzle for cleaning surfaces - Google Patents

Abstract

The invention relates to a method for cleaning surfaces of electronic components, wherein a blasting material is mixed with compressed air and fed to the surface to be cleaned by means of a nozzle (1), wherein the cleaning jet is mixed with ionized air, and relates to a blasting nozzle (1) for use in devices for cleaning surfaces of electronic components, consisting of a nozzle body (2) with a main channel (3), which comprises an axial inlet for a mixture of blasting material and compressed air and an axial outlet (6), wherein the blasting nozzle (1) has one or more secondary channels (4) for transporting and introducing ionized air into the mixture of blasting material and compressed air.

Description

 Method and jet nozzle for cleaning surfaces

The invention relates to a method for cleaning surfaces, in particular surfaces of electronic components, according to the Merkmaien of patent claim 1 and a jet nozzle for use in devices for cleaning surfaces, in particular surfaces of electronic components, according to the features of claim 4.

It is known to use electronic parts with e.g. To irradiate glass beads, natural granules or the like. This creates static charge on the electronic parts by the friction of the jet granules. The surface of the electronic parts is usually a carbon fiber. Through the use of antistatic agent, this resulting charge can be reduced but unfortunately not prevented. The static charge can be removed later by an ionized air shower, however, even before electronic components can be damaged.

The blasting process is usually carried out with jet granules and normal compressed air. In this case, the jet granules are mixed with the compressed air and fired at high speed onto the component to be irradiated, that is to be cleaned. Upon impact with the plastic surface of e.g. Duroplastteile creates a static charge of about 1000V to 20000V. This can not be prevented even with admixed antistatic but only reduced to about 00V to 1000V. Since the maximum limit for electronic components is zero volts, the static charge must be prevented before it occurs.

From US 2004/0194803 a method for cleaning electronic components is known in which ionized cleaned compressed air is used to remove impurities and residues of paint, etc. on the electronic component.

From WO2004 / 048006 A1 a method for separating dust particles from a granulate is known in which an air flow is passed through the granules, which entrains the dust particles, wherein the dust particles containing granules is introduced into a container. At least part of the air stream forming air is ionized. The ionization is carried out in such a way that the air flow is passed through a per se known, but not described, ionizing device.

From DE 37 411 777 A1 a device for dedusting of films, thin plates or films existing objects known. The device comprises an air duct through which cleaning air is blown transversely to the feed of the film to be cleaned on the surface to be cleaned. The air is ionized in the cleaning area, discharging electrostatic charges on the surface of the film and blowing it away.

From DE 36 03 041 A1 a surface cleaning device for dedusting of solid objects, in particular for the pre-cleaning of car bodies prior to painting is known, comprising a built-in Blasluftdüse. This blown air nozzle is in operative connection with an ionization device. In the ionisierungsvorrichtung dust particles are electrostatically charged and shot by means of the blower nozzle on the surface to be cleaned, where they neutralize the electrostatically adhering dust particles.

The object of the invention is to provide an improved method for preventing static charge of surfaces to be cleaned. Another task is to specify a corresponding jet nozzle.

These objects are achieved by the method according to the features of the valid patent claim 1 and with the jet nozzle according to the features of the valid patent claim 4. Advantageous embodiments of the invention are the subject of dependent claims.

The inventive method for cleaning surfaces of electronic components is characterized in that blasting material is mixed with compressed air and fed by means of a nozzle of the surface to be cleaned, wherein the rice Cleaning jet is mixed with ionized air. The blasting material is, for example, glass beads, natural granules or other agents which a person skilled in the art uses for cleaning surfaces.

In one embodiment of the invention, the cleaning jet is mixed with ionized air at the exit from the nozzle.

In a further embodiment of the invention, the cleaning jet is mixed in a region after leaving the nozzle and before impinging on the surface to be cleaned with ionized air.

The generation of ionized air and the acceleration of the mixture of ionized air with jet granules and compressed air on the surface to be treated of an electronic component are well known to a person skilled in the art and are not the subject of this invention.

The jet nozzle according to the invention for use in devices for cleaning surfaces of electronic components consists of a nozzle body with a main channel, which comprises an axial inlet for a mixture of blasting material and compressed air and an axial outlet. Furthermore, the jet nozzle has one or more secondary channels for the promotion and introduction of ionized air in the mixture of blasting and compressed air.

In one embodiment of the invention, the secondary channels Nebenkana- I au strittsöff now gene, which are arranged in a ring around the main channel. The axes of the Nebenkanalausirittsöffnungen run at an acute angle or at right angles to the axis of the main channel. It is expedient to have 4 secondary duct outlet openings which are arranged symmetrically around the main duct. The auxiliary channels assigned to the secondary duct outlet openings are expediently designed such that the ionized air guided in these secondary ducts is supplied at a predetermined angle, in particular between 10 ° and 90 °, to the mixture of blasting material and compressed air. A rotationally symmetrical arrangement of the side channel outlet openings around the main channel proves to be suitable as a result. net, since in such an arrangement can achieve optimal mixing of the mixture of blasting and compressed air with the ionized air.

The acceleration of the mixture of ionized air with blasting material and compressed air to predetermined speeds takes place with the fluidic means known to a person skilled in the art. Likewise, the supply of the corresponding media in the secondary or main channels according to a person skilled in the known means.

In a further embodiment of the invention, an annular secondary channel outlet opening is present around the main channel, wherein the annular secondary channel outlet opening is designed such that the outflowing ionized air is supplied to the mixture of blasting material and compressed air at an acute angle or right angle.

The invention and further advantages of the invention will be explained in more detail with reference to figures. Show it:

1 is a schematic representation of a jet nozzle in a first embodiment in plan view,

 2 is a schematic representation of a jet nozzle in a second embodiment in plan view,

 3 is a schematic Schnittdarsteliung by a jet nozzle according to the invention in a first variant,

 4 is a schematic sectional view through a blasting nozzle according to the invention in a second variant,

Fig. 1 shows a schematic representation of a jet nozzle in plan view. In this illustrated embodiment, the jet nozzle 1 by way of example four auxiliary channels 4, which are arranged symmetrically about the outlet opening 6 of the main channel 3. The nozzle body 2 has, in addition to the main channel outlet opening 6 of the main channel 3, the opening channel 5 of the exemplary four secondary channels 4. The axis H of the main channel 3 points out of the plane of the drawing. The axes N of the secondary channels 4 are indicated such that they intersect the axis H of the main channel 3. The intersection S of the axis H of the main channel 3 and the axes N of the secondary channels 4 is outside the plane of the drawing.

This makes it clear that the ionized air transported in the secondary channels 4 outside the nozzle body 2 and thus in the jet direction after the mixture of jet granules and compressed air from the main channel 3 of the jet nozzle 1 is mixed with the mixture of jet granules and compressed air.

Fig. 2 shows a further schematic representation of a jet nozzle in plan view. The same reference numerals mean the same objects. In this embodiment shown, the jet nozzle 1 has an annular secondary channel outlet opening 5, which is arranged around the main channel 5. The annular secondary channel 4 is designed concentrically to the main channel 5 in the nozzle body 2. The axis H of the main channel 3 is perpendicular to the plane of the drawing and the axis N of the annular secondary channel is oriented such that the two axes H and N intersect outside the plane of the drawing. In other words, the annular sub-channel is designed such that the flow direction of the outflowing ionized air in the direction of the axis H of the main channel 3 is aligned.

3 shows a schematic sectional illustration through a blasting nozzle according to the invention in a first variant, wherein this sectional illustration shown covers both the exemplary embodiment with several secondary channels and with an annular secondary channel. FIG. 3 thus shows a sectional illustration of FIGS. 1 and 2 along the section line A. FIG.

The illustration shows a jet nozzle 1 with a nozzle body 2 in which a main channel 3 and two secondary channels 4 arranged symmetrically to the main channel 3. The inlet of the main channel 3 and the inlets of the secondary channels 4 are not further illustrated. In addition, in the illustration, the reservoir for the jet granules and the compressed air and the device for the ionization of air, expedient of compressed air, not shown. The latter device is state of the art and not the subject of this invention. The connection of the main channel 3 and the Subchannels 4 to appropriate containers for storage and supply of the corresponding media is also prior art and not the subject of this invention.

 The axes N of the secondary channels 4 and the axis H of the main channel 3 intersect outside the nozzle body 2 at a point S. The angle a, under which the two axes N and H intersect, is less than 90 °. Suitably, the angle α is between 10 ° and 50 °. The point of intersection S of the two axes N and H is here seen in the flow direction behind the outlet opening 6 of the main channel 4 and in front of the surface to be cleaned (not shown).

FIGS. 4a and 4b show a schematic sectional view through a blasting nozzle according to the invention in a second variant, wherein the latter shown

Sectional view covering both the embodiment with multiple side channels and with an annular secondary channel. The same reference numerals mean the same objects.

 The axes N of the secondary channels 4 and the annular secondary channel and the axis H of the main channel 3 intersect at the point S, which lies within the nozzle body 2 and expediently on the axis H of the main channel 3. This results in the mixture of ionized air the secondary channels 4 with the mixture of blasting and compressed air in the main channel 4 before exiting the mixture of the jet nozzle. 1

In Fig. 4a, the axes N of the secondary channels 4 and the annular secondary channel and the axis H of the main channel 3 are arranged to each other such that the angle α between the two axes N and H is 90 °. In Fig. 4b, the respective axes N and H are arranged such that the angle α is between 10 ° and 50 °.

Of course, it is possible that in the examples shown in Fig. 3 and Fig. 4a, b, the axes N of the secondary channels 4 and the axis H of the main channel 3 intersect in several intersections S for the case of several secondary channels. As a result, a better mixing of the media from the secondary channels and the main channel can be achieved. A good mixing of the ionized air with the mixture of jet granules and compressed air ensures cleaning and irradiation of electronic components, without there being any static charge of these components.

This prevents destruction of the components.

reference numeral

1 jet nozzle

 2 nozzle housings

 3 main channel

 4 secondary canals

 5 secondary channel outlet opening

 6 main channel outlet opening

H main axis

 N minor axis

α angle

 S intersection point

Claims

claims

1. A method for cleaning surfaces of electronic components, wherein a blasting mixed with compressed air and by means of a nozzle (1) is supplied to the surface to be cleaned, characterized in that the cleaning jet is mixed with ionized air.

2. The method according to claim 1, characterized in that the cleaning jet at the outlet from the nozzle (1) is mixed with ionized air.

3. The method according to claim 1, characterized in that the cleaning jet is mixed in a region after leaving the nozzle (1) and before striking the surface to be cleaned with ionized air.

4. blasting nozzle (1) for use in devices for cleaning surfaces of electronic components, comprising a nozzle body (2) with a main channel (3) having an axial inlet for a mixture of blasting material and compressed air and an axial outlet (6) comprises, characterized in that the jet nozzle (1) has one or more secondary channels (4) for conveying and introducing ionized air into the mixture of blasting material and compressed air.

5. jet nozzle according to claim 4, characterized in that the secondary channels (4) have secondary channel outlet openings (5), which are arranged annularly around the main channel (3) and the axes (N) of the secondary channel outlet openings (5) at an acute angle (a) or right angle to the axis (H) of the main channel (3).

6. jet nozzle according to claim 4, characterized in that an annular secondary channel outlet opening (5) to the main channel (3) is present and the annular auxiliary channel outlet opening (5) is designed such that the outflowing ionized air the mixture of blasting and compressed air at an acute angle or right angle is supplied.