DE8807489U1 - Ultrasonic liquid atomizer - Google Patents

Description

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Applicant: Lechler GmbH & Co. KG, 7012 Fellbach

Ultrasonic liquid atomizer

Description

The invention relates to an ultrasonic liquid atomizer, with a piezoelectric transducer having ceramic disks, an electrode arranged between the ceramic disks, a liquid line and a connection for the liquid supply, with a nozzle centrally/axially connected to the transducer and with an atomizer plate arranged or formed at the end of the nozzle, wherein the nozzle has a central/axial bore forming the continuation of the liquid line in the transducer and serving to transport liquid to the surface of the atomizer plate <. |

An ultrasonic liquid atomizer of the aforementioned

This type has become known, for example, through DE-PS 32 33 901. &idiagr;

According to the current state of technology, such '

Ultrasonic liquid atomizers have a vibrating atomizer plate from which a certain amount of liquid is sprayed per unit of time. The atomizer plate is excited by a transducer equipped with piezoceramic disks. An amplitude transformer (so-called trunk) is arranged between the transducer and the atomizer plate. The vibration system of the transducer, trunk and atomizer plate works in one, preferably the lowest, i

Natural frequency. The size of the atomizer plate is given by |

determines the dimensions of the converter and the trunk and depends on the frequency at which the converter is operated.

Due to the circumstances described, there are limits to the maximum amount of liquid that can be nebulized. It would be conceivable to overcome these limits by using two

or more atomizers can be connected in parallel. However, this purely theoretical possibility fails due to the fact that each ultrasonic liquid atomizer requires its own feedback high frequency generator. A parallel arrangement of several atomizers would therefore result in high costs, which would make the use of such ultrasonic liquid atomizers uneconomical.

The object of the present invention is to find a way of increasing the amount of liquid atomized per unit of time by an ultrasonic liquid atomizer without connecting several ultrasonic liquid atomizers in parallel.

According to the invention, the object is achieved in an ultrasonic liquid atomizer of the type mentioned at the beginning in that a nozzle with an atomizer plate is arranged on each of the two front sides of the transducer and that the length of the common transducer is matched to the length of the two nozzles in such a way that oscillation nodes of the longitudinal oscillation with which the oscillation system oscillates are created at the transition points between the transducer and the nozzle.

By means of the measures according to the invention, the amount of liquid to be nebulized by an ultrasonic liquid atomizer can be doubled with little additional effort, whereby advantageously only a single high-frequency generator is required.

According to an embodiment that is very useful for the practical implementation of the invention, the handler has a length that corresponds to half the oscillation wavelength, and the length of the proboscis corresponds to a quarter of the oscillation wavelength, corrected for the mass of the atomizer plate. The entire oscillation system can thus be operated in its second longitudinal resonance.

Advantageous embodiments of this embodiment can be found in claims 3 and 4.

According to _another , also very advantageous embodiment of the invention, it is proposed that the transducer has a length corresponding to the oscillation wavelength and the length of the proboscis corresponds to a quarter of the oscillation wavelength, corrected for the mass of the atomizer plate, and that the piezoelectric ceramic disks with an intermediate electrode are arranged centrally between the two ends of the transducer.

In this embodiment, another vibration node is created in the middle of the transducer, so that this practically at rest center plane of the transducer represents an ideal location for arranging the piezoelectric ceramic disks and the electrode.

In an advantageous further development of this embodiment of the invention, it is proposed that each nozzle in the converter is assigned a separate, non-axially continuous liquid line with a liquid supply hole and connection, which are arranged near the respective converter front side. This variant makes it possible for two different liquids to be atomized simultaneously with just one atomizer, since each individual atomizer plate is connected to its own liquid supply.

Of course, it is also possible - alternatively - in the embodiment with the converter enlarged to twice the length, to provide a continuous liquid line with only a single liquid supply bore, including connection.

Further advantageous embodiments of the invention can be found in claims 7 and 8.

To illustrate and explain the invention in more detail, embodiments are shown in the drawing

and described in detail below. It shows:

Fig. 1 - schematically - an embodiment of an ultrasonic liquid atomizer according to the invention, in side view, and

Fig. 2 - also schematic - another embodiment of an ultrasonic liquid atomizer according to the invention, in a representation corresponding to Fig. 1.

The ultrasonic liquid atomizer shown in Fig. 1 consists of a rotationally symmetrical/cylindrical transducer 10 with a longitudinal central axis 11, which continues on its two end faces 12, 13 in a coaxial and centrally arranged nozzle 14 or 15. The transducer 10 has two piezoelectric ceramic disks 16, 17, between which an electrode 18, also designed as a disk, is arranged, forming the p-conductor for the electrical voltage supply of the transducer 10. An atomizer plate 19 or 20 is arranged at the free end of the nozzles 14 and 15. A liquid connection 21 is attached radially to the outer circumference of the transducer 10, which continues inside the transducer 10 in a correspondingly radial liquid supply bore 22. Connection 21 and liquid supply bore 22 are arranged near the front face 12 of the converter 10. The liquid supply bore 22 opens into an axially directed central liquid line 23, which runs through the converter along its entire length. The two nozzles 14 and 15 are also penetrated by corresponding central bores - numbered 24 and 25 - which are aligned with the liquid line 23 of the converter 10, are connected to it and open onto the surface - 27 or 28 - of the respective atomizer plate 19 or 20. The liquid supplied at 21 thus reaches the surfaces 27> 28 of the atomizer plates 19, 20, where it is nebulized by the vibrations of the atomizer plates 19, 20.

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In order to create suitable conditions for this, the individual areas of the ultrasonic liquid atomizer must be coordinated with one another in terms of their length dimensions. Thus, the length of the converter 10 in the embodiment according to Fig. 1 is half the wavelength (X/2) of the longitudinal oscillation waves with which the entire oscillation system works. The length of the nozzles 14, 15, on the other hand, is only a quarter (OL/4) of the oscillation wavelength in question, whereby these dimensions must be corrected for the mass of the atomizer plates 19, 20. Due to the conditions described, oscillation nodes are formed at 29 and 39, i.e. at the transitions of the converter 10 to the nozzles 14 and 15, at which the system is practically at rest. For this reason, the two piezoelectric ceramic disks 16, 17 with the electrode 18 connected between them have been placed close to the transducer front face 13 and thus close to the vibration node 30.

While the electrode 18 forms the ρ-conductor, a flange 31, which is arranged on the front side 12 of the transducer 10 or forms the front side 12 of the same, functions as the η-conductor. In a second function, the flange 31 also serves to fasten the entire ultrasonic liquid atomizer in a housing (not shown).

The embodiment according to Fig. 2 differs from the embodiment according to Fig. 1 in that the converter designated 10a is twice as long as the converter 10 according to Fig. 1. The length of the converter 10a according to Fig. 2 therefore corresponds exactly to one wavelength K . This results in a further oscillation node in the middle cross-sectional plane of the converter 10a, where the oscillation system is at rest. For this reason, in the embodiment according to Fig. 2, the two ceramic disks 16, 17 and the p-conductive electrode 18 are arranged exactly in the middle cross-sectional plane of the converter 10a. Another difference compared to Fig. 1 is the design.

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The design according to Fig. 2 is characterized in that the transducer 10a has a flange 31a on both sides, whereby these two flanges can in turn be used to fasten the entire ultrasonic liquid atomizer in a housing (not shown). One of the two flanges 31a can also function - just as in the embodiment according to Fig. 1 - as an η-conductive electrode.

The embodiment according to Fig. 2 differs from Fig. 1 in that no continuous liquid line is provided. Instead, a separate liquid line is provided at each end of the converter 10a, which is numbered 32 and 33 respectively. The two liquid lines 32 and 33 have only a comparatively small longitudinal extension and are each connected to their own liquid supply bore 22 and a liquid connection 21. The two nozzles 14 and the two atomizer plates 27 and 28 otherwise correspond to the embodiment according to Fig. 1. Due to the separate liquid supply to each of the two nozzles 14, 15, it is possible in the embodiment according to Fig. 2 to spray two different liquids at the same time.

The parts of the ultrasonic liquid atomizer according to Fig. 2 corresponding to the embodiment according to Fig. 1 are numbered with the same reference numerals as in Fig. 1. This serves to improve clarity and facilitate comparison of the two embodiments.

Claims (8)

Expectations 1. Ultrasonic liquid atomizer, with a ceramic disk, an electrode arranged between the ceramic disks, a liquid line and a connection for the liquid supply, with a piezoelectric transducer, with a nozzle centrally/axially connected to the transducer and with an atomizer plate arranged or formed at the end of the nozzle, whereby the nozzle has a central/axial bore forming the continuation of the liquid line in the transducer and serving to transport liquid to the surface of the atomizer plate, characterized in that a nozzle (14, 15) with an atomizer plate (27, 28) is arranged on each of the two end faces (12, 13) of the converter (10, 10a) and that the length of the common converter (10, 10a) is matched to the length of the two nozzles (14, 15) in such a way that oscillation nodes of the longitudinal oscillation with which the oscillation system oscillates are formed at the transition points (29, 30) of the converter (10, 10a) and the nozzle (14, 15). 2. Ultrasonic liquid atomizer according to claim 1, characterized in that the transducer (10) has a length corresponding to half the oscillation wavelength (\,/2) and the length of the proboscis (14, 15) each corresponds to a a · ■ Quarter of the oscillation wavelength ( X/4 ), corrected for the mass of the atomizer plate (27, 28), corresponds to (Fig. 1). 3. Oxtrasonic liquid atomizer according to claim 1 or 2, characterized in that the converter (10) has a continuous liquid line (23) which at each end leads into an axial bore (25 or 26) of the relevant nozzle (14 or 15) and a common liquid supply bore (22) which opens into the liquid line (23) at approximately a right angle (Fig. 1., 4. Ultrasonic liquid atomizer according to claim 1, 2 and 3, characterized in that the liquid supply bore (22) and the connection (21) adjoining it on the outer wall of the transducer (10) are arranged off-center near one transducer face (12) and the piezoelectric ceramic disks (16, 17) with an intermediate electrode (18) are arranged off-center near the other transducer face (13) (Fig. 1). 5. Ultrasonic liquid atomizer according to claim 1, characterized in that the transducer (10a) has a length corresponding to the oscillation wavelength (λ,) and the length of the proboscis (14, 15) corresponds to a quarter of the oscillation wavelength (λ/4), corrected by the mass of the atomizer plate (27 or 28) and that the piezoelectric ceramic disks (16, 17) with an intermediate electrode (18) are arranged centrally between the two ends (12, 13) of the transducer (10a) (Fig. 2). 6. Ultrasonic liquid atomizer according to claim 5, characterized in that each nozzle (14, 15) in the converter (10a) is assigned a separate, non-axially continuous liquid line (32 or 33) with liquid supply bore (22) and connection (21), which in are arranged near the respective converter front side (12 or 13), 7. Ultrasonic liquid atomizer according to one or more of the preceding claims, characterized in that the transducer (10) has a flange (31) on the front side, which forms the η-conductive electrode of the oscillation system and at the same time serves to fasten the ultrasonic liquid atomizer in a housing (Fig. 1). 8. Ultrasonic liquid atomizer according to one or more of claims 1-6, characterized in that the converter (10a) has flanges (31a) on both sides, which serve to hold the ultrasonic liquid atomizer and to hermetically seal the high-voltage-carrying part of the converter (10a) (Fig. 2).