DE9017338U1 - Flow vessel for a disintegrator - Google Patents

Description

Flow vessel for a disintegrator

The invention relates to a flow vessel for a disintegrator.

Disintegrators are used, for example, in

medical sector for the disruption of cells, bacteria and fungi and in the industrial sector for wastewater homogenization, the production of emulsions, the dispersion of powder in liquids or for the dispersion

of agglomerates in biology. A flow vessel is used into which a sonotrode designed as an ultrasonic transducer is immersed, whereby the medium to be processed flows through the flow vessel. The sonotrode is

by a sound transducer connected to a high frequency generator, to high frequency vibrations. The position of the sonotrode in the flow vessel must usually be adjusted to achieve good efficiency and

Maximum energy can be adjusted so that

certain distances between the sonotrode end and an opposite impact plate

be respected.
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The invention is based on the object of creating a flow vessel for a disintegrator, which enables control of the efficiency and supplies the medium to be processed with a maximum of energy.

This object is achieved according to the invention by the characterizing features of the main claim. Due to the fact that a flow nozzle with a baffle plate opposite the end of the sonotrode is

which is adjustable in height, it is possible to control the efficiency and, in addition, to limit the space between the sonotrode and the opposite impact plate in such a way that a maximum of energy is delivered to the

the medium to be processed. This makes adjustment easy even if the sonotrode is changed.

By the means specified in the subclaims

Advantageous further developments and improvements are possible through these measures. It is particularly advantageous that, due to the cuts in the area where the sonotrode is attached to the housing, the vibrations are decoupled

from the housing. It is also particularly advantageous that both the end of the sonotrode and the impact plate are provided with a cavitation protection layer made of polycrystalline diamond, as this significantly reduces cavitation damage.

In this way, the

integrators, as the sonotrodes need to be replaced less frequently and high performance can be achieved, with improved

continuous processes can be used to process the different media.

Embodiments of the invention are described in

Drawing and are explained in more detail in the following description. Shown are:

Fig. 1 a device in block diagram

for processing a liquid, for example for stabilizing a dispersion using a design that provides a flow vessel according to the invention

integrators,

Fig. 2 a section through an embodiment of a flow vessel,

Fig. 3 a top view of the upper part

of the vessel casing with the cutting line for the incisions,

Fig. 4 the side view of the upper

Part of the housing as shown in Fig. 3 with cutouts for vibration decoupling,

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Fig. 5 a partial section through the

Sonotrode used in the flow vessel according to the invention,

Fig. 6 a partial section of a second

Embodiment of a sonotrode used in the flow vessel according to the invention, and

Fig. 7 a partial section through a

Third embodiment of the sonotrode used in the flow vessel according to the invention.

In Fig. 1 the flow vessel according to the invention is

shown,

whereby a sonotrode 3 is immersed in the flow vessel 1. The flow vessel 1 is connected to a storage container via an inflow line 4 and a valve 6 controlled by a microprocessor

connected. A drain line 8 leads from the flow vessel l into a collecting tank 9. Furthermore, a cooling circulation line 10 is connected to the flow vessel, which serves to cool it. A high frequency generator 11 supplies

Sound transducer 12 generates the vibrations which are transmitted via a step horn 13 to the sonotrode 3, which transmits them as axial vibrations to the medium flowing through the flow vessel 1.

For example, the storage container 7 contains an emulsion that is to be stabilized. The microprocessor 5 controls the flow rate via the valve 6, whereby the emulsion is fed via the inflow

line 4 into the flow vessel 1.

In the area below the sonotrode 3, the phases of the emulsion are homogenized due to the pressure waves and after treatment, the processed emulsion is discharged via the drain line

8 into the collection container 9. The flow can be controlled continuously or discontinuously by the microprocessor 5, whereby, however, continuous processing is carried out.

Fig. 2 shows a section through the flow vessel 1. The housing 14 of the flow vessel 1 consists of a jacket 15 and a pipe 16 connected to the jacket 15, the jacket being connected to the pipe 16 at the fastening points.

cracks, such that an annular gap 17 is formed between the casing 15 and the tube 16. The tube

16 has an inlet 18 and an outlet 19, which are connected to the cooling line 10 and to the annular gap 17, so that the cooling medium

the jacket 15 of the flow vessel 1 in the annular gap

17 can flow around. The rod-shaped sonotrode 3, which forms a unit with the step horn 13, is inserted into the upper end of the housing 14 and is screwed to the housing via a thread 20.

A flow nozzle 21 is screwed into the casing 15 from below, with seals 22 provided as ring seals for sealing between the casing 15 and the flow nozzle 21. The flow nozzle 21 has a central bore 23

which is connected to the inflow line 4. In the upper area of the flow nozzle 21, a baffle plate 24 is inserted, which has a central bore 25 and is located opposite the end of the sonotrode 3.

The flow nozzle 21 is adjustable in height,

i.e. it can be screwed more or less far into the housing, i.e. the casing. In this way, the distance to the end of the sonotrode 3 can be adjusted in such a way that a maximum of energy can be delivered to the cavity 26 formed in the housing through the bore 23. The processing area of the medium lies between the sonotrode 3 and the impact plate 24. A drain connection 27 is provided

with the drain line 8.

To ensure that the standard horn 13 does not transmit vibrations to the casing 14 of the housing, measures for vibration reduction are required as shown in Fig. 3 and 4.

coupling is provided. The two figures refer to the upper area of the casing 15, into which the step horn 13 with the sonotrode is screwed. In Fig. 4 it can be seen that the casing 15 is provided with incisions 28, 29 in different

height. Fig. 3 shows the cutting path of the saw disks for the cuts 28, 29 at the different heights.

The sonotrode 3 and the standard horn 13 consist

preferably made of titanium or a titanium alloy, the end of the sonotrode having a cavitation protection layer 30. This cavitation protection layer is shown in more detail in several embodiments in Figs. 5, 6 and 7. In the end

the sonotrode 3 has a blind hole 31 with a thread, into which the threaded socket 32 of a plate 33 is screwed. An organic film or organic layer or a

Ductile metal foil is inserted, which acts as a damping

layer 34 serves to dampen radial vibrations. It has been shown that the coupling of different material pairs, for example titanium and steel, from which the plate is preferably made

exists, can cause difficulties when screwed together at high amplitudes and power densities, as occur in disintegrators. When the sonotrode 3 is excited, both axial vibrations and radial strain waves are generated, which

are of different sizes due to the different materials. This creates friction between the screwed surfaces, which leads to abrasion and the vibration decoupling of the sonotrode 3 and the screwed-on plate 33. Due to the

The damping layer 34 arranged between the sonotrode 3 and the plate 33 dampens the radial waves, while the axial vibrations are transmitted to the plate 33 without impairment. The damping layer 34 preferably has

a thickness of approximately 25 to 75 μm.

On the plate 33, the cavitation is prevented by means of brazing material 35, which has a melting temperature of < 750 C, with the interposition of a carrier 36.

protective layer 30 is applied, which consists of polycrystalline diamond sintered onto the carrier 36.

In Fig. 6, the cavitation protection layer 30

made of polycrystalline diamond with the carrier 36 made of hard metal directly to the end of the sonotrode, whereby the soldering process is carried out under vacuum or inert gas via a hard solder 37 connected to the titanium, which has a melting temperature of> 800° C

and a brazing solder applied thereto

38, which has a melting temperature of < 750 C.

Fig. 7 shows an embodiment,

which is particularly suitable for small diameters of the sonotrode 3, preferably for diameters of 1 mm to 3 mm. A blind hole 39 is made in the end of the sonotrode 3 and in addition a very small transverse

hole 40, for example with a diameter of 0.1 mm to 0.3 mm, which is connected to the blind hole 39. Adhesive, preferably epoxy resin, is introduced into the blind hole 39 and the carrier 36 is connected to the cavitation

protective layer 30 made of polycrystalline diamond is pressed into the hole filled with epoxy resin. The excess adhesive 41 is pressed into the cross hole 40 and runs off if necessary. The remaining wall 42 of the

Sonotrode 3 has a bead that engages positively in a groove made in the hard metal 36. Since the edge of the sonotrode 3 remains cavitation-free for physical reasons, no signs of wear occur there.

Claims (11)

&bull; · I &bull;&bgr; 9 O Protection claims 1. Flow vessel for a disintegrator with a housing having an inlet and an outlet through which a the medium flows in or out of a cavity provided in the housing, with a connector closing the cavity, which can be inserted into the housing and with a rod-shaped Sonotrode, which is coupled to a sound transducer and transmits its vibrations to the medium,
characterized in that the nozzle is designed as a flow nozzle (21) is formed with a bore (23) connected to the inlet (4), the bore (23) opening into the cavity (26) opposite the end of the sonotrode (3) and that the flow nozzle (21) for opti ization of the efficiency and setting of a defined distance to the sonotrode (3) is adjustable. 2. Flow vessel according to claim 1, characterized characterized in that the housing (11) is provided with incisions (28, 29) in the area of the fastening of the sonotrode (3) for vibration decoupling. 3. Flow vessel according to claim 1 or 2, characterized in that a baffle plate (24) is arranged between the flow nozzle (21) and the end of the sonotrode (3). 4. Flow vessel according to one of the claims 1 to 3, characterized in that the housing (14) is double-walled, wherein an intermediate space (17) is provided in the double wall through which a cooling medium flows. 5. Flow vessel according to one of claims 1 to 4, characterized in that the oscillating end of the sonotrode (3) and the Impact plate (24) is provided with a cavitation protection layer (30) made of polycrystalline diamond applied to a metal carrier (35). 6. Flow vessel according to claim 5, characterized in that the metal carrier (36) of the cavitation protection layer (30) is connected to a plate (33) made of steel by brazing, the plate (33) in the end of the sonotrode (3) is screwed in. 7. Flow vessel according to claim 5 or 6, characterized in that between the end of the sonotrode (3) and the plate (33) a damping layer (34) is arranged. 8. Flow vessel according to claim 7, characterized in that the damping layer (34) as an organic layer, organic film or ductile metal foil. 9. Flow vessel according to claim 5, characterized in that the metal carrier (33) of the cavitation protection layer (30) is directly connected to the Titanium-containing end of the sonotrode (3) is connected by brazing under vacuum or inert gas. 10. Flow vessel according to claim 5, characterized characterized in that the end of the sonotrode (3) has a blind hole (39) into which the cavitation protection layer (30) with metal carrier (36) is glued, wherein the wall (42) of the blind bore (39) contains a bead which positively engages in a groove made in the hard metal (36). 11. Flow vessel according to claim 10, characterized characterized in that the blind bore (39) is connected to a transverse bore (40) which serves to receive and drain off adhesive (41).