WO2015172996A1 - Device for focusing a viscous medium discharged from a discharge opening of a discharge device of a jet device, jet system, and production plant - Google Patents

Abstract

The invention relates to a device (5) for focusing a viscous medium discharged from a discharge opening (3) of a discharge device (2) of a jet device (1), comprising means for producing a gas flow (11) and a nozzle device (7) having at least one gas outlet (9) and an opening (8) for the viscous medium.

Description

 description

title

 Apparatus for focusing one out of an output port of a

Output device of a jet device issued viscous medium, jet system and production plant

State of the art

The invention is based on a device for focusing a viscous medium dispensed from a dispensing opening of a dispensing device of a jet device, a jet system and a production plant as generically defined by the independent claim.

For the contactless dosing of drops of a viscous medium, for example an adhesive or a solder, onto a substrate, jetting is known. An apparatus and a method for jetting drops are known, for example, from WO1999 / 064167 AI. Herein, the viscous medium is in an output chamber and is jetted from a dispensing valve by a rapid reduction in the volume of that dispensing chamber.

Disclosure of the Invention Advantages of the Invention

The inventive device for focusing one of a

The dispensing opening of a dispensing device of a jet device issued viscous medium has the advantage that the shape and / or direction of the viscous medium can be influenced by means of the device. In this way, for example, it can be influenced which shape the viscous medium has after striking a substrate.

Another advantage of the device according to the invention is that so-called satellites, which may be present as undesirable side drops in addition to a main drop of the viscous medium after the dispensing of the viscous medium, can be directed into the main drop by means of the device through a gas flow directed to the viscous medium, and thus prevents the side drops or satellites in unwanted places on the

Impact substrate.

The device according to the invention serves to focus the viscous medium by means of the gas flow. Focusing is to be understood here as meaning that a diameter of the viscous medium in at least one direction when impacting on the substrate is reduced in relation to that

Diameter without focus. Thus, it is advantageously made possible by the device according to the invention to achieve particularly small structures in jetting. It can be achieved dimensions of structures of up to 50 μηη.

Another advantage of the device according to the invention is that a particularly compact design of the device can be achieved by the nozzle device. Several functions are simultaneously integrated into the nozzle device by at least one gas outlet located in the nozzle device and an opening for the viscous medium located in the nozzle device.

By the at least one gas outlet of the nozzle device, the

Gas flow occurs before impinging on the viscous medium, the direction and shape of the gas stream can be adjusted specifically. No separate means are needed to manipulate the gas flow. If the device according to the invention for changing applications with

different requirements are applied to the directed to the viscous medium gas stream, this can only be a change of

Sufficient nozzle device. There is no need to change the entire apparatus for focusing the dispensed viscous medium. The fact that the nozzle device has a port for the viscous medium results in that the nozzle device can be arranged centrosymmetrically about the path which the viscous medium travels either in the dispenser or between the dispenser and the substrate. Thereby, the nozzle device can be directly attached to or near the discharge port of the jet device without the nozzle device being in the way of the viscous medium. It is possible in a simple way a particularly accurate positioning of the gas outlet and thus also a particularly accurate adjustment of the gas flow with respect to the viscous medium.

Another advantage of the device according to the invention is that it makes it possible to increase the distance between the dispensing opening of the dispenser and the substrate, for example to 5 mm or larger, without losing sight of accuracy. This makes it possible to apply by Jetten also small structures of the viscous medium on substrates having a surface unevenness of greater than 3 mm. Such a big one

Asperities typically include three-dimensional circuit carriers such as Molded Interconnected Devices, pressure sensors, electrical circuits, and flexible electrical circuits.

Due to the particularly compact design of the device according to the invention, this is particularly well suited for use in a space-critical application, for example in a production plant. This also ensures a particularly easy retrofitting into an existing structure for jetting a viscous medium.

These advantages are achieved by the device according to the invention for focusing a viscous medium dispensed from a dispensing opening of a dispenser of a jet device, means for generating a gas flow and a nozzle device having at least one gas outlet and a viscous medium opening. The measures listed in the dependent claims advantageous refinements and improvements of the main claim device for focusing a from a discharge opening of a

Output device of a jet device issued viscous medium possible.

It is particularly advantageous if the opening for the viscous medium for receiving the dispensing device is configured. By this is meant that the dispenser is inserted into the opening for the viscous medium. In this case, for example, the nozzle device directly on the

Output device are mounted, whereby the at least one gas outlet of the nozzle device is automatically aligned in the radial direction with respect to the opening for the viscous medium. In this case, it is particularly preferred if the opening for the viscous medium has a geometry which is suitable for a positive connection with the lateral surface of the

 Output device is designed.

When the opening for the viscous medium for receiving the

Output device is configured, it is also particularly advantageous if the nozzle device is designed such that the opening for the viscous

Completes the medium of the nozzle device in a plane with the output port of the dispenser. In this case, advantageously, the orientation of the nozzle device in the axial direction with respect to the opening for the viscous medium is predetermined.

In a positive connection between the opening for the viscous medium and the lateral surface of the dispenser in this case, an intrusion of the viscous medium in the area between the

Nozzle device and the dispenser are avoided because there is no gap between the nozzle device and the dispenser.

In an advantageous development of the device according to the invention, the device has means for fastening the device to the dispensing device of the jet device. This prevents that there is a relative movement between the nozzle device and the dispenser can come. Thus, the generated gas stream is always exactly aligned with the path the viscous medium travels between the dispenser and the substrate. Furthermore, a particularly compact construction is made possible by the attachment of the device to the dispenser, since no separate, mounted in the vicinity of the device fasteners are needed.

Furthermore, it is advantageous if the means for attachment to the dispenser of the jet device are designed for static attachment of the device to the dispenser. As a result, a particularly stable connection is achieved.

Alternatively, however, it is also advantageous if the means for attachment to the dispenser of the jet device allow rotation of the nozzle device around the dispenser or around the opening for the viscous medium. By a rotation of the nozzle device to the

Output device is also the emerging from the at least one gas outlet gas stream in a rotation about the viscous medium.

As a result, with a correspondingly fast rotation of the gas stream, it can be achieved that with only one gas stream rotating around the viscous medium, for example satellites which can form around the viscous medium in all directions can be directed into the main drops of the viscous medium.

By virtue of the fact that, when the gas flow around the viscous medium is rotated with only one gas flow, the viscous medium between the output device and the substrate can be influenced from all radial directions, the gas can be achieved with the same flow rate of the supplied gas as compared with arrangements with several gas streams is brought to a particularly high speed. Accordingly, a further advantage of this arrangement is that it is not necessary in this case to divide the gas stream into a plurality of partial gas streams, which then a correspondingly lower

Flow rate would have. The nozzle device to store on the dispenser so that a rotation around the opening for the viscous medium is made possible, represents a structurally particularly simple way for the rotation of the gas stream to the viscous medium.

In an advantageous development of the device according to the invention, the nozzle device has a plurality of gas outlets for dividing the gas flow into a plurality of partial gas flows. As a result, a particularly accurate manipulation of the shape and the direction of the viscous medium is possible. Furthermore, as a result of this, molds that are different from a round shape of the viscous medium after impinging on the substrate can be adjusted in a particularly simple manner, such as, for example, an oval or line-like shape.

It is particularly advantageous if the device according to the invention comprises a gas outlet arranged annularly around the opening for the viscous medium. In this way, in a structurally particularly simple manner, a gas stream which is isotropically focusing the viscous medium on its path between the output device and the substrate is produced. Thus, it becomes possible to provide particularly uniformly circular drops on the substrate by means of the device according to the invention.

In an advantageous development of the device according to the invention, at least one of the gas outlets has a conical shape. As a result, the diameter of the gas stream is reduced and the flow rate is increased.

Furthermore, it is advantageous if at least one gas outlet has an inclination to the normal to the nozzle device plane. In this way, an inclined gas flow to the jet axis, ie the connecting line between the discharge opening of the jet device and the point of impact of the viscous medium on the substrate, can be generated. But it is also possible to provide at least one gas outlet with a slope that does not extend exclusively in the direction of the jet axis. Due to the inclination, it is possible to generate a gas flow which, upon storage of the nozzle device allowing rotation about the viscous medium port, rotates the nozzle device offset. In this case, the gas flow serves as a drive means for the rotation of the nozzle device.

A jet system, which is to be understood as a combination of a jet device and a device according to the invention, and a production system with a device according to the invention likewise show the advantages of the device according to the invention listed above.

Embodiment drawings

Embodiments of the invention are illustrated in the drawings and explained in more detail below. Show it:

Figure 1 is a view of a cross section of an output device for a

 viscous medium of a jet device with a device for carrying out the method according to the invention,

Figure 2 cross sections of nozzle devices with different geometries.

Description of the embodiment

FIG. 1 shows a detail of a jet device 1. The jet device 1 has an output device 2 for dispensing the viscous medium, for example in the form of a jet valve, a jet needle or a jet nozzle. In particular, this may be a plunger valve, a resonance pressure valve or an aerosoljet valve.

The invention will be described below without loss of generality with reference to a jet valve as the output device 2. The viscous medium is discharged from a discharge port 3 of the dispenser 2. Typical diameter of the discharge opening 3 of the

Output device 2 are in the range between 50 and 4000 μηη.

The viscous medium may be, for example, a fixing adhesive or a conductive adhesive. For example, conductive conductive adhesives such as, for example, the commercially available Heraeus PC3001 or Henkel Ablebond 84-1 LMI SR4 are used as conductive adhesives.

The viscous medium is dispensed in the form of drops from the discharge opening 3 of the jet valve and strikes a substrate 4 after a flight phase.

Depending on the shape of the dispensing opening 3 and depending on whether the substrate 4 remains static or is moved, various geometries of the viscous medium at the impact location on the substrate 4 are adjustable. For example, it is conceivable to use dispensing devices 2 with one or more dispensing openings 3.

Furthermore, in FIG. 1, a device 5 according to the invention for focusing the viscous medium dispensed from the discharge opening 3 of the jet device 1 is attached to the jet valve. Preferably, as shown in Figure 1, the attachment of the device 5 to the jet valve via a Schraubklemmverbindung. 6

However, structures are also conceivable in which the device 5 for focusing the viscous medium is not fixedly attached to the jet valve. For example, it is conceivable to provide an attachment, preferably by means of ball bearings, of the device 5 according to the invention to the dispensing device 2, which allows rotation of the nozzle device 7 of the device 5 according to the invention around the opening for the viscous medium. This can be realized, for example, in that 5 ball bearings are mounted on the device according to the invention, which are received by a flange, which in turn can be attached to the dispenser 2. Furthermore, it can be seen from FIG. 1 that the device 5 for focusing the viscous medium comprises a nozzle device 7. This has an opening 8 for the viscous medium. Preferably, as shown in Fig. 1, the viscous medium port 8 for receiving the dispenser 2 is configured, that is, the dispenser 2 is inserted into the viscous medium port 8.

Furthermore, as shown in FIG. 1, the opening 8 for the viscous medium of the nozzle device 7 is preferably adapted to the contour of the dispensing device 2, so that a positive connection results. Furthermore, the opening 8 for the viscous medium of the nozzle device 7 is dimensioned such that the nozzle device 7 terminates in a plane with the discharge opening 3 of the dispensing device 2.

In this embodiment, the nozzle device 7 on two continuous gas outlets 9. The gas outlets 9 serve to supply gas in the direction of the dispensed viscous medium.

The gas can be passed directly through the gas outlets 9 or by means of focusing nozzles 10 introduced into the gas outlets 9. The latter is the case in the exemplary embodiment shown in FIG. On the side facing away from the substrate 4, the focusing nozzles 10 are connected to the gas supply. Alternatively, the gas supply can also be directly to the

Gas outlet 9 are attached. For example, by a conical inlet of the gas outlets 9 or the Fokussierdüsen 10, the gas stream 11 can be additionally accelerated.

As a means for generating the gas stream 11, the gas can be made available, for example, via a domestic network or, for example, via a gas cylinder and, for example, via a hose system to the gas outlet 9 or the focusing nozzle 10. This is not shown in FIG. Suitable gases are, for example inert gases such. As nitrogen or alternatively, for example, air. From the discharge port 3 of the dispenser 2 of the jet apparatus 1, the viscous medium is discharged. This is done in the form of a main drop, from which undesirable secondary drops can split off. Of the

Main drops and the sub-drops fly from the discharge port 3 of the jet apparatus 1 toward a destination on the substrate 4.

By means of the device 5 for focusing the output medium, a gas stream 11 or in the embodiment shown in Figure 1, two partial gas streams 12, 13 are generated, which in the direction of the jet axis 14, ie the connecting line between the discharge port 3 of the jet device 1 and the impact of the viscous medium on the substrate 4, are directed.

This is achieved by the gas passages in the nozzle device 7 and the focusing nozzles 10, which lead through the nozzle device 7, are inclined at an angle to the jet axis 14. This angle is preferably less than 45 ° and preferably greater than 3 °. Through the gas passages 9 and the opening of the focusing nozzles 10, a laminar gas flow 11 is preferably generated.

Likewise, in an alternative embodiment to the embodiment shown in FIG. 1, it is conceivable to provide the gas outlets 9 with an inclination which does not extend exclusively in the direction of the jet axis 14.

By the inclination, it is then possible to produce a gas flow 11, the nozzle device 7 set at a storage of the nozzle device 7, which allows rotation about the opening 8 for the viscous medium in rotation. In this case, the gas stream 11 serves as a drive means for the rotation of

Nozzle device 7.

During the flight of the viscous medium or of the main droplet, the gas stream 11 hits or, in this case, the two partial gas streams 12, 13 strike the viscous medium. As a result, the secondary drops are directed into the main drops.

Furthermore, the main drop is compressed by the gas flow 11, so focused, so that this with a smaller diameter at its Destination hit on the substrate 4, as would have been the case if no gas flow 11 had been directed to him.

It is not only conceivable that the focusing of the main droplet takes place uniformly from all directions in order to achieve a round shape of the droplet after impinging on the substrate 4. The focusing can also be done, for example, by the arrangement of the gas outlets 9

different directions take place in different degrees, so that adjusts a deviating from a round shape geometry of the drop on the substrate 4.

By means of the arrangement shown in Fig. 1, the drop is brought, for example, in a form which is formed perpendicular to the plane of the paper oblong. A focusing directed at the paper level does not take place here. If, as in this embodiment, the case, the focus of the droplet is not out of all

In the same way, if the droplets are impinged on the substrate 4, the droplet can thus even have a larger diameter in the directions in which no focusing takes place than would have been the case if no gas stream 11 had been directed at it.

Typical flow rates for the gas stream 11 are between 20 and 200 cm ³ / n in the gas or air used for the gas stream 11.

The nozzle device 7 shown in Figure 1 can in different

Be configured geometries. For example, these may be two, three or four

Have gas outlets 9. Examples of geometries of the nozzle device 7 are shown in FIG.

FIG. 2a shows a cross-section of the nozzle device 7, as used in the construction shown in FIG. In the middle is the opening 8 for the viscous medium. The two further openings are the two gas outlets 9.

FIG. 2b shows a cross-section of a nozzle device 7 with a centrally arranged opening 8 for the viscous medium and three gas outlets 9. FIG. 2 c shows a cross-section of a nozzle device 7 with a centrally arranged opening 8 for the viscous medium and four gas outlets 9.

FIG. 2d shows a cross-section of a nozzle device 7 with a viscous medium opening 8 in the middle and a gas outlet 9 arranged annularly around the viscous medium opening 8. Through such a shaped gas outlet 9, the viscous medium is particularly evenly focused from all directions; it results after the impact of the drop on the substrate 4, a round geometry of the drop.

In order to ensure a cohesion of the regions of the nozzle device 7 outside and inside the annular opening of the gas outlet 9 in the nozzle device 7 shown in Figure 2d, these are interconnected by two webs.

The webs have the smallest possible width in order not to hinder the gas flow 11 in the passage through the gas outlet 9. The webs are in a different plane than that shown in Figure 2d

Cross-sectional plane, so that the webs are not shown in Figure 2d.

As materials for the production of the nozzle device 7 come

For example, metals or plastics in question. Typical thicknesses of

Nozzle device 7 are 1000 to 3000 μηη, but there are also larger or smaller thicknesses possible. The holes or the gas outlets 9 in the nozzles have a diameter between 10 and 1000 μm, preferably between 50 and 500 μm.

The distance between the discharge opening 3 of the dispenser 2 and the substrate 4 is usually in the range of a few millimeters, for example between 0.5 and 3 mm. By means of the device 5 according to the invention it is possible to further increase the distance between the dispensing opening 3 of the dispensing device 2 and the substrate 4, for example to 5 mm or larger, without losing sighting accuracy. This makes it possible thanks to the device 5 according to the invention to apply by Jetten also small structures of the viscous medium on substrates 4, which have a surface unevenness of greater than 3 mm. Such a large surface unevenness usually have three-dimensional circuit carriers, such as Molded Interconnected Devices, pressure sensors, electrical circuits and flexible electrical circuits.

By means of the method according to the invention, it is possible to focus the viscous medium at the target location on the substrate 4 to a diameter of only 50 μm. When using the device 5 according to the invention together with a jet device 1, for example, conductor tracks, for example as a replacement of wire bonds, and contacts of passive and active

Components are jetted with small connection geometries.

In the embodiment shown in Figure 1, the discharge port 3 of the jet valve is not in the gas stream 11. However, embodiments are also conceivable in which the discharge port 3 of the output device 2 of the jet device 1 is detected by the gas stream 11. In this way it can be achieved that no residues of the viscous medium remain at the dispensing opening 3. The gas flow 11 thus serves in this case to clean the dispensing opening 3.

Furthermore, in this embodiment, the gas flow 11 can serve to optimize the tear-off behavior of the viscous medium at the discharge opening 3, so that, for example, there is no satellite formation.

Depending on the type of application, the viscous medium used and the desired diameter of the viscous medium after striking the target location, for example, the angle at which the gas stream 11 is directed to the viscous medium, or the number of

Partial gas streams 12, 13 or, for example, the flow rate can be adjusted.

In this case, for example, the volume flow of the gas stream 100 cm ³ / nnin amount, the nozzle device with two diametrically arranged gas outlets have an opening diameter of 100 μηη and the gas flow at an angle of 30 ° to the jet axis to be inclined. As a result, a metering distance of between 5 and 8 mm is achieved for a process-reliable application of the conductive adhesive to the substrate for the above-mentioned, typically used conductive adhesives.

Claims

claims

A device (5) for focusing one of an output port (3) of a

 Dispensing device (2) of a jet device (1) issued viscous medium, characterized by means for generating a gas stream (11) and a

 Nozzle device (7) with at least one gas outlet (9) and an opening (8) for the viscous medium.

2. Device (5) according to claim 1, characterized in that the opening (8) for the viscous medium for receiving the output device (2) is configured.

3. Device (5) according to claim 2, characterized in that the

 Nozzle device (7) is designed such that the opening (8) for the viscous medium of the nozzle device (7) terminates in a plane with the discharge opening (3) of the dispensing device (2).

4. Device (5) according to any one of the preceding claims, characterized by means (6) for attachment to the output device (2) of the jet device.

5. Device (5) according to claim 4, characterized in that the means (6) for attachment to the output device (2) of the jet device (1) designed for static attachment of the device (5) on the output device (2) are.

6. Device (5) according to claim 4, characterized in that the means (6) for attachment to the output device (2) of the jet device (1) allow rotation of the nozzle device (7) to the output device (2).

7. Device (5) according to one of the preceding claims, characterized by a plurality in the nozzle device (7) located gas outlets (9) for dividing the gas stream (11) into a plurality of partial gas streams (12, 13).

8. Device (5) according to any one of the preceding claims, characterized by an annular arranged around the opening (8) for the viscous medium

 Gas outlet (9).

9. Device (5) according to one of the preceding claims, characterized by a conical shape of at least one gas outlet (9).

10. Device (5) according to one of the preceding claims, characterized

 characterized in that at least one gas outlet (9) has a slope to the normal to the nozzle device plane.

11. Jet system with a device (5) according to one of claims 1 to 10.

12. Production plant with a device (5) according to one of claims 1 to 11.