DE202014101462U1 - Device for generating liquid mist - Google Patents

Abstract

Device having at least two jet nozzles (D1, D2) arranged spaced apart from one another on a nozzle carrier (DT), which are adapted to produce bundled liquid jets (S1, S2) and which are aligned at an angle to each other such that the liquid jets (S1, S2 ) in an impact point (P) meet, characterized in that the distance (a) of the nozzle orifices (DM) from each other and the inclination angle (β) between the liquid jets (S1, S2) are coordinated so that the point of impact (P) at such a distance from the nozzle orifices (DM) that they remain free from the liquid mist (N) generated when the liquid jets meet.

Description

The invention relates to a device for generating liquid mist with a predetermined component of motion, wherein at least two angularly aligned sharply focused liquid jets S ₁ , S ₂ in an impingement point P which is spatially away from the jet nozzles D ₁ , D ₂ , meet leaves.

The liquid mist N is commonly used for wetting or coating substrates. Particularly preferably, different types of liquids are to be mixed in an impact point or in the liquid mist, possibly in conjunction with other fluids, gases, low-viscosity liquids or the like. A method is from the DE 10 2012 204 426 A1 known. The method for spray coating an article with a hot melt adhesive described in this document teaches ejecting a molten hot melt adhesive through a first die and a second die such that a first melt stream exiting the first die and a second melt stream exiting the second die are sharpened Angle meet each other so that forms a Sprühfächer, wherein the nozzles are maintained at a predetermined target temperature. By maintaining the target temperature, a desired viscosity of the hot melt adhesive should be achieved to thereby maintain the desired droplet size of the spray fan. The angle of inclination of the melt jets should always be an acute angle between 10 ° and 80 °. About the distance of the nozzle orifices of the melt jets are given in the aforementioned document no information.

It has now been found that there is a risk in the embodiment that, in particular when the spraying discontinuously, d. H. Thus, with interruptions, running, by uncontrolled backflow wetting of the nozzle openings takes place through the generated liquid mist and thus there is a risk of contamination or clogging of the nozzles.

Object of the present invention is to improve a generic device so that such a backflow and thus contamination of the nozzle orifices is excluded. At the same time, the user should be allowed to set a mixing ratio and the degree of mixing in the spray as a function of different liquids. Also, the wear of the nozzles over the useful life

are
a ₁ , a _{2 are} the distances of the nozzle orifices DM of the jet nozzles D ₁ , D ₂ to the solder from the point of impact P on the connecting line V of the nozzle orifices DM of the jet nozzles D ₁ , D ₂ ,
b is the distance of the point of impact P from the connecting line V of the nozzle orifices DM and
β ₁ , β _2, the angle of inclination of the liquid jets S ₁ , S ₂ to the solder from the point of impact P on the connecting line V of the nozzle orifices DM,
Thus, the object is achieved according to the invention in that the distances a ₁ , a ₂ , the inclination angle β ₁ , β ₂ and the distance b are coordinated so that the nozzle orifices DM remain free from the generated liquid mist.

The coordination of the quantities a _n , β _n and b can be carried out empirically by experiments. Preferably, and in a further embodiment of the invention, for example for generating a liquid mist N from two liquid jets S ₁ and S ₂ , the distance a of the nozzle orifices DM according to the formula a = b · (tan β ₁ + tan β ₂ ), where a = a ₁ + a ₂ and β = β ₁ + β ₂ are adjusted. In this coordination of the sizes a, b and β wetting of the nozzles by the generated liquid mist can be reliably avoided if experience shows that the distance b is greater than 10 mm, even if the inclination angle β = β ₁ + β ₂ between the Liquid jets have an angle ≥ 80 °.

For a particularly intensive nebulization of the liquid jets angle of inclination β of more than 80 ° in particular obtuse angles are desirable. In a further embodiment of the invention is therefore proposed that the inclination angle β of the liquid jets S ₁ , S _{2 is} between 30 ° and 120 °. Especially the range of larger angles of inclination between 80 ° and 120 ° brings, as far as the nebulization, particularly good results in terms of achievable small droplet size of the liquid.

Depending on the viscosity of the liquid to be atomized in another embodiment of the invention, the liquid pressure in the nozzle and the nozzle orifice cross-section should be coordinated so that a jet velocity v at the nozzle orifice of 15-150 m / sec. results. In this case, it is preferable to set the jet velocity, starting from a low value and a low viscosity of the liquid to be atomized, proportionally to the viscosity of the atomized liquid.

Particularly advantageous results can be achieved if at a viscosity of the liquid of 400 mPa · s (milli-Pascal second) an exit velocity of 150 m / sec. is set.

The number of liquid jets that are allowed to collide to produce directional liquid mist N at the point of impact P can be as already indicated above by the phrase "at least two", amount to more than two.

In an advantageous embodiment of the device, in which at least two, preferably three, liquid jets meet at the point of impact P, at least one of the liquid jets should be controllable with respect to the direction and / or the jet velocity. As a result, both the shape and the direction of movement of the generated spray fan or the liquid mist N can be adjusted. In the case of different liquids, it is thus also possible to control or adjust the mixture pattern and / or the mixing ratio.

In a further embodiment of the device according to the invention, it is provided that, in addition to the liquid jets S ₁ ... S _n, a gas jet GS is directed onto the point of impact P. Depending on the liquid used, in particular on the viscosity of the liquid used, the atomization can be improved by the use of an additional gas jet GS. In addition, the use of an additional gas jet GS creates the possibility of finely distributing substance components, for example glue for glue, which is mixed with the gas jet GS into the liquid mist N, which can bring advantages depending on the use or environment of the liquid mist.

Finally, it should be provided in a further embodiment of the device that the liquid jets S ₁ ... S _n consist of different liquids. In this case, not only a generation of liquid mist N is achieved from a liquid, but in addition also an intensive mixing of the liquids used.

The device is thus characterized essentially with at least two jet nozzles D ₁ , D ₂ arranged at a distance from one another on a nozzle carrier DT, which are adapted such that they produce bundled liquid jets S ₁ , S ₂ and which are oriented at an angle to one another such that the Liquid jets S ₁ , S ₂ meet at a point of impact P on each other. Such a device is again from the above-mentioned document DE 10 2012 204 426 A1 . 2 and related description.

As stated above, it is an object of the present invention to improve such a device so that on the one hand high-grade atomization of the liquid used takes place, on the other hand wetting or contamination of the nozzle orifices is avoided with certainty.

According to the invention, the distances a ₁ , a _{2 of} the nozzle mouths DM of the jet nozzles D ₁ , D ₂ to the solder from the point of impact P on the connecting line V of the nozzle orifices DM, and the inclination angle β ₁ , β _{2 of} the liquid jets S _1, S ₂ to the solder from Point of impact P on the connecting line V of the nozzle orifices DM be coordinated so that the point of impact P is at a distance from the nozzle orifices, that they remain free from the liquid mist N generated when the liquid jets S ₁ , S ₂ meet. In an advantageous embodiment of this teaching, for example for generating a liquid mist N from two liquid jets S ₁ and S _2, the distance of the nozzle orifices DM a = b · (tan β ₁ + tan β ₂ ), where a = a ₁ + a ₂ and β = β ₁ + β ₂ , b is the distance of the impact point P from the connecting line V of the nozzle orifices DM and β ₁ , β _{2 are} the angles of inclination of the liquid jets S ₁ , S ₂ to the solder from the point of impact P on the connecting line V of the nozzle orifices DM , It has been shown that, while maintaining this dependence between the sizes a, b and β excellent fogging results can be achieved while avoiding any wetting of the nozzle orifices.

The device according to the invention undergoes a further embodiment in that a plurality of jet nozzles D ₁ -D _n , preferably regularly and / or annularly distributed on the nozzle carrier DT are arranged so that all exiting liquid jets lie on the mantle of a cone whose tip is the point of impact P. In such an embodiment, the angles of inclination β ₁ ... Β _{n of} the liquid jets S ₁ ... S _n to the perpendicular from the point of impact P to the nozzle plane, which are defined by the nozzle orifices DM, are preferably between 15 ° and 60 °.

In an arrangement of a plurality of jet nozzles D _n , which generate liquid jets S _n having the same inclination angle β ₁ = β ₂ = ... = β _n , the cone opening angle is 2 × β ₁ and should preferably be between 30 ° and 120 ° lie. The advantage of an arrangement with several jet nozzles is that higher quantities of liquid can be atomized and a uniform, preferably circular and / or cone-shaped spray fan is obtained.

In an advantageous embodiment of the device according to the invention, at least one of the jet nozzles D ₁ -D _n on the nozzle carrier DT should be arranged variable in their position and / or their orientation. By such a design, the orientation or the shape of the generated liquid mist N can be selected depending on the setting of the variable nozzle DV.

In addition, it is possible to switch the liquid jet at individual or all jet nozzles DV discontinuous and thus time-dependent to obtain a differently shaped liquid mist N. In particular, it may be advantageous to use pulsed nozzles, whereby it can then arrive again on the substrate to be sprayed.

In a further embodiment of the device according to the invention, it is proposed that in addition to the jet nozzles D ₁ -D _n for liquids, a gas nozzle DG adapted for a gaseous fluid be provided. Depending on the type of liquid used, such a design can help to make the nebulization more effective and with even finer droplet size. The arrangement of the gas nozzle DG for gaseous fluid is preferably selected centrally with respect to the arranged jet nozzles D ₁ ... D _n for liquids. In this case, the gas nozzle DG has the smallest distance b to the impact point P.

Another possibility would be to arrange one of the nozzles D ₁ -D _n for liquids centrally with respect to the other jet nozzles D ₁ -D _n to dispense an additional liquid preferably discontinuously without affecting the liquid mist N in its direction and extent. The person skilled in the art will, within its capabilities, use known control and regulation mechanisms (valves, measuring instruments, flow meters, control and / or regulating means) in order to achieve or optimize the result to be achieved.

In a particularly advantageous manner, the device can be used in the course of the production of material plates, in which case sprayed with these nozzles, the adhesive fleet (glue, hardeners, aggregates ...) on the still loose material (chips, fibers, nonwoven ....) becomes. Advantageously, in particular the glue (isocyanate or the like) is mixed with a hardener prior to impact with the loose material, usually in a chute or a mixer, and in each case proportionally sprayed onto the material. Advantageously, the degree of mixing and the impact with the invention can be adapted to the circumstances.

The device will be explained by way of example with reference to the accompanying drawings. In the drawings shows:

1 a basic schematic representation of the device for generating liquid mist N from two liquid jets S ₁ , S ₂ ,

2 a first embodiment of a device as in 1 shown,

3 an alternative embodiment of a device according to 2 with a nozzle DV which can be changed according to position and orientation,

4 a further alternative embodiment of the device according to 2 with a central gas nozzle DG and

5 a plan view against the nozzle carrier DT in the direction of jet nozzle mouths DM on a device accordingly 2 however with three jet nozzles.

For a better understanding, the distances a, b and angle β according to the invention are once again defined. The distance a defines the distance between the nozzle orifices DM. A _{1 is the} distance of the nozzle orifice DM from the nozzle D ₁ to the solder from the point of impact P on the connecting line V. Accordingly, a _{2 is} the distance of the nozzle orifice DM of the nozzle D ₂ to the solder of Impact point P on the connecting line V. In general, with a plurality of nozzles, the distance a _{n of} the nozzle mouth DM of the nozzle D _n to the solder from the impact point P on the connecting line V. b defined the distance of the connecting line V to the impact point P. The angle β shows the angle of inclination between the liquid jets S ₁ -S ₂ , β ₁ the angle of inclination of the liquid jet S ₁ to the solder from the point of impact P on the connecting line V, β ₂ the angle of inclination of the liquid jet S ₂ to the solder from the point of impact P on the connecting line V and accordingly for several Angle β _n the angle of inclination of the liquid jet S _n to the solder from the point of impact P on the connecting line V.

In the schematic representation after 1 are two spaced-apart jet nozzles D ₁ and D ₂ shown, from which one can leak bundled liquid jets S ₁ , S ₂ . The direction of the liquid jets S ₁ , S ₂ is indicated by vectors. The vectors are not true to scale, but partly serve in their different length in the figures as an indication of different jet velocities v. The pressure necessary for the production of the bundled liquid jets S ₁ , S ₂ is established in a conventional manner above the nozzle orifices, which is not shown in detail. The jet nozzles D ₁ and D ₂ are arranged so that their nozzle orifices DM have a distance of a. Furthermore, the jet nozzles D ₁ , D ₂ are aligned so that the exiting liquid jets S ₁ , S ₂ against each other assume an inclination angle β = β ₁ + β ₂ and the two liquid jets S ₁ , S ₂ in one point, namely the point of impact P, meet each other. When the liquid jets S ₁ , S ₂ meet at the point of impact P, they are atomized in very fine droplets to form a liquid mist N. The liquid mist N extends substantially within the angle of the downwardly continued beam directions S ₁ , S ₂ . However, a certain uncontrolled backflow in the direction of the jet nozzles D ₁ , D ₂ can not be prevented by the meeting of the two bundled liquid jets S ₁ , S ₂ . Thus, this return flow of liquid fog does not reach the nozzle orifices, the arrangement being such that the distances a _1, a ₂ of the nozzle orifices DM of the jet nozzles D _1, D ₂ on the connecting line V of the nozzle orifices DM and the inclination angle β to the perpendicular from the impingement point P ₁ , β _{2 of} the liquid jets S ₁ , S ₂ to the solder from the point of impact P on the connecting line V of the nozzle orifices DM via the relationship a = b · (tan β ₁ + tan β ₂ ), where a = a ₁ + a ₂ and β = β ₁ + β ₂ , should be chosen so that the distance b of the point of impact P from the connecting line V of the nozzle orifices DM is greater than 10 mm.

If one were to choose a smaller angle of inclination β for the two liquid jets S ₁ , S ₂ than that in FIG 1 is shown, the result would be after the above-mentioned dependence between the inclination angle β and the distance a greater possible distance b of the impact point P to the connecting line V. Conversely, at a certain inclination angle β, the distance a should be greater according to the formula shown to choose to obtain a distance b greater than 10 mm and thus to reliably avoid a backflow from the liquid mist N to the nozzle orifices DM of the jet nozzles D ₁ , D ₂ . By changing the above formula, a desired limit of the distance b depending on the distance a = a ₁ + a ₂ and the inclination angle β = β ₁ + β ₂ can be determined: b = a / (tan β ₁ + tan β ₂ ). At a fixed distance a = 30 mm, an inclination angle β = 90 ° leads to a distance b = 15 mm. At an inclination angle β = 115 ° to a distance b = 9.55 mm.

For the in 2 schematically illustrated device are the same reference numerals as in 1 selected. The device comprises a substantially cylindrical nozzle carrier DT whose central axis is denoted by TM. At the nozzle carrier DT jet nozzles D ₁ and D ₂ are arranged in such a way that the exiting bundled liquid jets S ₁ , S ₂ meet again in the point of impact P at an angle β of substantially 90 °. The resulting liquid mist is denoted by N.

In the 3 illustrated embodiment of a device according to the invention is shown in a view as the 2 equivalent. One of the jet nozzles D _n , which is denoted by DV in the figure, should be changeable in its position and its orientation, which thereby 3 is indicated that the nozzle orifice DM is located eccentrically to the nozzle main axis H of the nozzle DV. Thus, by means of an eccentric rotation of the nozzles, the vector of the liquid jet and thus the position of the point of impact could be changed. The appearance of the liquid mist N also changes respectively. Alternatively or in combination, the nozzle can also be swiveled, which is represented by a swivel range W as a bow arrow on the nozzle DV. Alternatively or in combination, the nozzle DV along a linear movement X can be moved to adjust the impact point P accordingly.

Corresponding to the asymmetrically positioned nozzle DV and, consequently, the changed position of the liquid jet emerging from the nozzle DV, an asymmetrically formed liquid mist N results, both as regards the shape and its position in space. The adjustment of the variable nozzle DV takes place depending on the desired position and shape of the liquid mist N. The arrangement of a variable nozzle DV is in combination with one or more other nozzles D _N (eg in 5 ) possible. In the case of different liquids, it would then be in the advantageous position nevertheless to form a symmetrical liquid mist N and thus, in particular with a large number of devices next to one another, to generate a large-area spray pattern with adjacent and / or overlapping spraying cones. Also occurring with the help of adjustable jet nozzles DV wear or other occurring during production changes to the devices can be compensated and a uniform possible spraying over time to be ensured.

It would accordingly be possible, in adaptation to the local conditions, to provide a nozzle carrier DT in which different angles β _{n of} the jet nozzles D _{n are} provided, which are adapted to the corresponding liquids in order to obtain optimum liquid mist N.

In the further embodiment of a device according to the invention according to 4 in addition to the liquid jet nozzle D a central gas nozzle DG arranged, the gas jet GS also on the impact point P of the liquid jets from the jet nozzles _n S _n D _n is addressed yet. Depending on the viscosity of the liquid used, the use of a, in particular central, gas jet GS can once again increase or at least adapt the fogging quality. It may also be useful in the course of atomization to increase the energy content of the individual components in the liquid mist N, for example with steam, in particular in order to improve the mixing itself.

In the embodiment according to 5 , with the view from below against the nozzle carrier, are altogether three jet nozzles (in 5 denoted by D _n ) are provided which are regularly distributed on a circular ring, so that the angular distance from one nozzle D _n to the next 120 °.

List of Reference Numerals: UP1475

• a

  distance

  a ₁

  distance

  a ₂

  distance

  a _n

  distance

  b

  distance

  β

  tilt angle

  β ₁

  tilt angle

  β ₂

  tilt angle

  β _n

  tilt angle

  D ₁

  jet

  D ₂

  jet

  D _n

  nth nozzle

  DG

  gas nozzle

  DM

  nozzle orifice

  DT

  nozzle carrier

  DV

  jet

  GS

  gas jet

  H

  main axis

  N

  mist

  P

  impact point

  S ₁

  liquid jet

  S ₂

  liquid jet

  S _n

  liquid jet

  TM

  longitudinal axis

  V

  connecting line

  v

  jet speed

  W

  swivel range

  X

  linear motion

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102012204426 A1 [0002, 0014]

Claims (9)

Device having at least two jet nozzles (D ₁ , D ₂ ) arranged at a distance from one another on a nozzle carrier (DT), which are adapted to produce concentrated liquid jets (S ₁ , S ₂ ) and which are aligned at an angle to each other such that the jets of liquid (S ₁ , S ₂ ) in an impact point (P) meet, characterized in that the distance (a) of the nozzle orifices (DM) from each other and the inclination angle (β) between the liquid jets (S ₁ , S ₂ ) so matched in that the point of impact (P) lies at such a distance from the nozzle orifices (DM) that they remain free of the liquid mist (N) generated when the liquid jets meet. Apparatus according to claim 1, characterized in that the distance (a) of the nozzle orifices (DM) according to the formula a = b · (tan β ₁ + tan β ₂ ) is set, wherein a = a ₁ + a ₂ and a ₁ and a _{2 are} the distances of the nozzle openings (DM) of the jet nozzles (D ₁ , D ₂ ) to the solder from the point of impact (P) on the connecting line (V) of the nozzle openings (DM) of the jet nozzles (D ₁ , D ₂ ), where applicable Inclination angle β = β ₁ + β ₂ and β ₁ or β _{2 are} the angles of inclination of the liquid jets (S ₁ , S ₂ ) to the perpendicular from the point of impact (P) on the connecting line (V) of the nozzle orifices (DM) and where (b) the distance of the connecting line (V) to the point of impact (P) are. Device according to claims 1 or 2, characterized in that a plurality of jet nozzles (D ₁ -D _n ), in particular regularly and / or annularly distributed on the nozzle carrier (DT) are arranged so that all the exiting liquid jets (S ₁ -S _n ) lie on the mantle of a cone whose tip is the point of collision (P). Apparatus according to claim 3, characterized in that the opening angle of the cone is between 30 ° and 120 °. Device according to one or more of the claims, characterized in that at least one of the jet nozzles (D ₁ -D _n ) on the nozzle carrier (DT) is arranged variable in their position and / or their orientation. Device according to one or more of the claims, characterized in that in addition to the liquid nozzles (S ₁ -S _n ) a gas nozzle (DG) adapted for a gaseous fluid is provided. Device according to one or more of the claims, characterized in that a gas nozzle (GS) is arranged in addition to the nozzles (D _n ). Device according to one or more of the claims, characterized in that the nozzles (D _n ) are suitable for different liquids. Device according to one or more of the claims, characterized in that the nozzles (D _n ) are suitable for different components of an adhesive liquor, in particular at least for glue and an associated hardener.

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