EP2272591B1 - Stirring ball mill - Google Patents

Description

The invention relates to a stirred ball mill according to the preamble of the independent claims 1 and 2.

Agitated ball mills are used, for example, for comminuting or dispersing solids in a liquid phase, in particular for products from nanotechnology, but also, for example, for dye suspensions, coating colors, printing inks, agrochemicals, filler suspensions, cosmetics, foodstuffs, pharmaceuticals or microorganisms.

In this case, the material to be ground or dispersed in a liquid is introduced into the grinding chamber through the inlet arranged at one end of a grinding chamber and is ground or dispersed therein. The material is thereby successively moved through the grinding chamber, whereupon the ground or dispersed material is passed through a separating member, e.g. can be removed through a dynamic separation gap or through a slotted screen, and then through an outlet arranged at the inlet end. When operating the stirred ball mills, a fundamental distinction is made between the passage mode and the circulation mode.

In Passagenfahrweise the material to be ground or to be dispersed is pumped from a first container through the agitator ball mill into a second container. In order to achieve a desired fineness of the ground or dispersed Guts (product), if necessary, the good be pumped from the second container again by the agitator ball mill in another container, and so on (multi-pass mode).

In the circulation mode, the material to be ground or to be dispersed is pumped from a container into the agitator ball mill and back into the same container until the desired fineness of the ground or dispersed product (product) is reached. The basic operation of such stirred ball mills is known and, for example, in the EP 0 627 262 or the DE 2 215 790 described.

In stirred ball mills, different separation techniques are used to separate the ground or dispersed product from the grinding media. Examples include dynamic separation gaps, which consist of a rotor and a stator, and screens, such as slot screens. Due to the higher throughput area, a higher throughput is generally achievable with screens. However, the passage through the slots of the slot sieves can be hindered inter alia by gas bubbles, if the material to be ground is not degassed before entering the grinding chamber. In addition, the space containing the gas bubbles is not available for grinding or dispersion, and gas bubbles can lead to crusting and sticking of the grinding media and / or the material to be ground or dispersed. This results in a reduction of grinding performance and, in extreme cases, can lead to a blockage of the agitator ball mill. When gas bubbles occur in the material, the bubbles are further comminuted by turbulence and grinding media, which also foams and This can lead to an even stronger blockage of the screen. The pressure in the grinding chamber can thereby increase considerably and become so high that in extreme cases the operation of the stirred ball mill must be interrupted.

The WO-A-03/004168 discloses a stirred ball mill with a valve through which gas is precipitated together with the ground product from the grinding chamber. In this outlet valve, the product outlet and the gas outlet form a common channel over their entire length.

It is therefore an object of the invention to improve a stirred ball mill of the type mentioned in that the aforementioned problems no longer occur or at least greatly reduced.

This object is achieved according to the invention by a stirred ball mill, as characterized by the features of the independent claims 1 and 2. Advantageous embodiments of the inventive agitator ball mill are the subject of the dependent claims.

In the venting system according to the invention for removing gaseous components from the grinding chamber, the centrifugal force generated by the agitator with its stirring elements is used to separate the gaseous components, in particular gas bubbles, from a solid suspension. In the centrifugal force field, the solid suspension and the media are flung outward due to their higher density (as compared to the gas bubbles), while the gas bubbles, e.g. Air bubbles, stay in the central area (approximately in the center). This separation effect is basically independent of the type and shape of the stirring elements of the agitator. Due to the gas outlet in the central region of the grinding chamber at the outlet end of the same, the grinding chamber can be "vented" in this way. Depending on the design of this gas outlet, the gas outlet may preferably be provided with a sieve in order to prevent a flow of grinding media.

Here are several variants conceivable. Thus, in one embodiment of the agitator ball mill according to the invention, the agitator on a shaft on which the stirring elements are fixed, and extending in the axial direction extending gas outlet channel through the Wave through.

Thus, in a further exemplary embodiment of the agitator ball mill according to the invention, the product outlet for the ground or dispersed material is likewise arranged in the central region of the outlet-side end wall, which comprises a product outlet channel extending in the axial direction through the outlet-side end wall. In this case, the product outlet channel and the gas outlet channel are formed as separate outlet channels. In an alternative solution, the outlet of the gas outlet channel opens into the product outlet channel in front of the outlet of the product outlet channel. As a result, a kind of Venturi effect can be achieved, in that the air can be entrained by the outflowing product.

In a further embodiment of the agitator ball mill according to the invention, a separating element permeable to the ground or dispersed material (eg a slotted screen) is arranged in front of the product outlet or in front of the product outlet channel such that the ground or dispersed material is only in the essential radial direction through the separating element can pass through and then into the product outlet or the product outlet. Thus, the ground or dispersed product, which has been urged radially outwards by the centrifugal force, can flow in the radial direction through the separating member back in the direction of the product outlet arranged centrally in the outlet-side end wall. The grinding media are thereby retained by the separating member, while the milled or dispersed product with the desired specifications (particle size) can flow through the separating member (eg the slotted screen) towards the product outlet. The separating member may be formed as a cylindrical sieve cartridge, wherein the gas outlet passage in the axial direction passes centrally through the interior of the sieve cartridge. The cylindrical screen cartridge can be easily replaced or cleaned, should this be necessary.

As already mentioned, in one embodiment of the agitator ball mill at the inlet of the gas outlet or the gas outlet channel may be arranged a sieve, which is designed so that it retains at least the grinding media in the grinding chamber.

To enhance the vent, the outlet of the gas outlet or the gas outlet channel can be connected to a vacuum tank. The product, which is sucked in by the vacuum, can be separated and fed separately back to the inlet of the agitator ball mill.

As already mentioned, the type and shape of the stirring elements on the shaft of the agitator can be optimally chosen according to the purpose. In particular, the agitator a Have elle, are fixedly mounted on the stirring elements as paddle wheels, discs or pins.

Fig. 1

einen Ausschnitt aus einem Ausführungs- beispiel einer Rührwerkskugelmühle, dass von der Erfindung nicht umfasst ist.

Fig. 2

einen Ausschnitt aus einem Ausführungsbeispiel einer erfindungsgemässen Rührwerkskugelmühle, dass von der Erfindung nicht umfasst ist.

Fig. 3

einen Ausschnitt aus einem ersten Ausführungsbeispiel der erfindungsgemässen Rührwerkskugelmühle,

Fig. 4

einen Ausschnitt aus einem zweiten Ausführungsbeispiel der erfindungsgemässen Rührwerkskugelmühle, und

Fig. 5

ein drittes Ausführungsbeispiel der erfindungsgemässen Rührwerkskugelmühle mit einem mit dem Gasauslasskanal verbundenen Vakuumbehälter.

Further advantageous aspects of the agitator ball mill according to the invention will become apparent from the following description of exemplary embodiments with the aid of the drawing. In a schematic representation:

Fig. 1

a section of an embodiment of an agitator ball mill that is not included in the invention.

Fig. 2

a section of an embodiment of an inventive agitator ball mill that is not included in the invention.

Fig. 3

a section of a first embodiment of the inventive agitator ball mill,

Fig. 4

a section of a second embodiment of the inventive agitator ball mill, and

Fig. 5

a third embodiment of the inventive agitator ball mill with a connected to the gas outlet duct vacuum container.

In Fig. 1 is a section (outlet end) of a first embodiment of the inventive agitator ball mill 1 shown, in which a gas outlet channel 140 out through the outlet-side end wall 100 of the grinding chamber 10 out. The separate product outlet or product outlet channel is not shown in this embodiment. On the shaft 130 of the agitator 13 stirrers 131 are arranged, which are formed as disks.

In Fig. 2 is a section (outlet end) of a second embodiment of the inventive agitator ball mill 1a with an axially extending through the shaft 130a of the agitator 13a gas outlet channel 140a. In this embodiment, the gas discharge passage 140a is not led out through the discharge side end wall 100a of the grinding chamber 10a, but instead, it is carried out outwardly in the shaft 130a of the agitator. Also in this embodiment, the stirring members 131a are similar to the embodiment according to FIG Fig. 1 , designed as discs.

In Fig. 3 is a section (outlet end) of a third embodiment of the inventive agitator ball mill 1b to recognize, with the grinding chamber 10b and with the shaft 130b of the agitator 13b, on which stirrers 131b are arranged in the form of Schaufelradartigen accelerators. The gas outlet channel 140b passes centrally through the interior of a screen cartridge 150b, but is not led out of the grinding chamber 10b as a separate gas outlet channel 140b, but instead opens into the product outlet channel 120b in the region of the outlet end wall 100b. In this way, a kind Venturi effect can be achieved, namely by the gaseous components, such as gas bubbles are entrained by the pumped through the Produktauslasskanal 120b solid suspension.

In Fig. 4 is a section (outlet side end) of a fourth embodiment of the inventive agitator ball mill 1c to recognize, in which in the region of the end of the shaft 130c of the agitator 13c in addition to the blade-like stirrers 131c (accelerators), an additional stirrer 131c on the shaft 130c can be seen. Moreover, in this embodiment, the gas discharge passage 140c is separately led out of the grinding chamber 10c through the sieve cartridge 150c and through the outlet side end wall 100c, thus discharging, unlike the embodiment Fig. 3 - not in the product outlet channel 120c.

In Fig. 5 is a schematic representation of a fifth embodiment of the inventive agitator ball mill 1d shown with a vacuum container 2, which is connected to the gas outlet channel 140d of the agitator ball mill 1d. The fifth embodiment of the agitator ball mill 1 according to the invention again comprises a cylindrical grinding chamber 10d and an inlet 11 arranged at one end of the grinding chamber 10d for the material to be ground or dispersed, for example a solid suspension. Through the inlet 11, the material to be ground or to be dispersed can be fed to the grinding chamber 10d. In the grinding chamber 10d are in operation - - typically spherical - grinding media (not shown), which consist for example of a ceramic or other highly abrasion-resistant material. In the grinding chamber 10d, the agitator 13d rotatable about the chamber axis as a rotation axis 101d is also arranged, on the shaft 130d of which stirring elements 131d are fixedly arranged.

Furthermore, the embodiment of the agitator ball mill 1d according to Fig. 5 a product outlet 12 for the ground or dispersed material arranged at the other end (outlet-side end) of the grinding chamber 10d. The product outlet 12 comprises a product outlet channel 120d, which extends through the outlet-side end wall 100d of the grinding chamber 10d and here exemplarily has the shape of a pipe section with a curvature. Furthermore, in Fig. 1 a gas outlet 14 is provided in the form of a gas outlet channel 140d, which is arranged at the outlet end of the grinding chamber 10d in the central region and is exemplified here as a separate piece of pipe, which is led out of the grinding chamber 10d separated from the pipe section designed as a product outlet 120d.

Furthermore one recognizes in Fig. 5 in the region of the outlet-side end of the grinding chamber 10d, a separating member 15 in the form of a cylindrically shaped sieve cartridge 150d with a (not shown) slotted screen, through which the milled or dispersed material can pass only in a substantially radial direction (from outside to inside), so that it can then enter the product outlet channel 120d. In principle, however, the separation of the ground or dispersed material and the grinding media can also be carried out in other ways, for example with the aid of rotating separation gaps or other suitable methods.

In the in Fig. 5 In the embodiment of agitator ball mill 1d shown, agitators 131d are again designed as accelerator-type accelerators in order to convey the grinding bodies and the material to be ground or to be dispersed radially to agitator shaft 130d. By the rotation of paddle wheel-like agitators 131d (accelerators) acts on the grinding media a centrifugal force, which conveys the grinding media radially outward.

As already mentioned, it can occur when gas bubbles occur in good to the problems mentioned there (crust formation and bonding of the grinding media and / or to be ground or to be dispersed Guts, reduction of grinding performance, eventual blockage of the stirred ball mill, even stronger foaming, screen block , Increase in pressure in the grinding chamber, eventual interruption of operation). Since the density of the solid suspension is greater than the density of any gaseous components, e.g. Gas bubbles, the gas bubbles accumulate in the central region of the grinding chamber 10d. These can now be discharged to the outside through the gas outlet channel 140d which is likewise arranged in the central region (ie in the region of the center) at the outlet end, so that foaming can either be avoided or at least greatly reduced.

The outlet of the gas outlet channel 140d, which is passed through the outlet-side end wall of the grinding chamber 10d, is here connected to the already mentioned vacuum container 2, which in turn is connected to a vacuum pump 3. So that no grinding media can flow out of the grinding chamber 10d, a sieve can be arranged at the inlet of the gas outlet channel 140d (not shown). The vacuum pump 3 generates a negative pressure in the vacuum container 2, whereby the gaseous components are discharged from the grinding chamber 10d through the gas outlet channel 140d extending centrally through the interior of the screen cartridge 150d in the axial direction. If small amounts of Solid suspension are sucked by the negative pressure from the grinding chamber, they can be separated in the vacuum tank 2 and then fed by means of the feed pump 4 the ground or dispersed Good, which either discharged or possibly via the inlet 11 back into the grinding chamber 10d (or to a batch tank) can be returned.

The invention has been described with reference to the above embodiments of the agitator ball mill. However, the invention is not to be understood as being limited to these embodiments. Rather, numerous changes and variants of such a stirred ball mill are conceivable without departing from the technical teaching of the invention. By way of example only, it should be mentioned that in principle the gas outlet can also be designed as an outlet opening and does not necessarily have to include a channel, even if the exemplary embodiments described all have such a gas outlet channel. The scope of protection is thus defined by the following claims.

Claims (7)

1. Agitator ball mill (1c; 1d) for finely grinding or dispersing a material, having a cylindrical or conical grinding chamber (10c; 10d) for accommodating grinding elements and for receiving the material that is to be ground or dispersed,
   having an inlet arranged at one end of the grinding chamber (10c; 10d) for the material that is to be ground or dispersed,
   having an agitator (13c; 13d) extending axially into the grinding chamber (10c; 10d), with stirring means (131c; 131d) for moving the grinding elements and the material that is to be ground or dispersed in the grinding chamber (10c; 10d),
   and having a product outlet, arranged at the other end of the grinding chamber (10c; 10d), for the ground or dispersed material,
   wherein at the outlet of the grinding chamber (10c; 10d), in the central region, there is arranged a gas exhaust through which gaseous components, but no grinding elements, can be discharged from the grinding chamber (10c; 10d), the gas exhaust comprising an axially extending gas exhaust channel (140c; 140d), and the axially extending gas exhaust channel (140c; 140d) extending through a closure wall (100c; 100d) arranged at the outlet end, said closure wall delimiting the cylindrical or conical grinding chamber (10c; 10d), and wherein the product outlet for the ground or dispersed material is also arranged in the central region of the closure wall (100c; 100d) at the outlet end and comprises a product outlet channel (120c; 120d) which extends axially through the closure wall (100c; 100d) at the outlet end, characterised in that the product outlet channel (120c; 120d) and the gas exhaust channel (140c; 140d) are embodied as outlet channels separate from one another.
2. Agitator ball mill (1b) for finely grinding or dispersing a material, having a cylindrical or conical grinding chamber (10b) for accommodating grinding elements and for receiving the material that is to be ground or dispersed,
   having an inlet arranged at one end of the grinding chamber (10b) for the material that is to be ground or dispersed, having an agitator (13b) extending axially into the grinding chamber (10b), with stirring means (131b) for moving the grinding elements and the material that is to be ground or dispersed in the grinding chamber (10b),
   and having a product outlet, arranged at the other end of the grinding chamber (10b), for the ground or dispersed material, wherein at the outlet end of the grinding chamber (10b), in the central region, there is arranged a gas exhaust through which gaseous components, but no grinding elements, can be discharged from the grinding chamber (10b), the gas exhaust comprising an axially extending gas exhaust channel (140b), and the axially extending gas exhaust channel (140b) extending through a closure wall (100b) arranged at the outlet end, said closure wall delimiting the cylindrical or conical grinding chamber (10b), and wherein the product outlet for the ground or dispersed material is also arranged in the central region of the closure wall (100b) at the outlet end and comprises a product outlet channel (120b) which extends axially through the closure wall (100b) at the outlet end, characterised in that the exit end of the gas exhaust channel (140b) opens into the product outlet channel (120b) before the exit end of the product outlet channel (120b).
3. Agitator ball mill according to one of claims 1 or 2, in which a separating means (150b; 150c; 150d) through which the ground or dispersed material but not the grinding elements can pass is arranged in front of the product outlet or in front of the product outlet channel (120b; 120c; 120d) such that the ground or dispersed material can only pass through the separating means (150b; 150c; 150d) in a substantially radial direction and can then enter the product outlet channel (120b; 120c; 120d).
4. Agitator ball mill according to claim 3, characterised in that the separating means is embodied as a cylindrical screening cartridge (150b; 150c; 150d), and wherein the gas exhaust channel (140b; 140c; 140d) extends centrally through the interior of the screening cartridge (150b; 150c; 150d) in the axial direction.
5. Agitator ball mill according to anyone of the preceding claims, characterised in that at the entrance to the gas exhaust channel (140b; 140c; 140d) a screen is arranged which is configured so as to retain at least the grinding elements in the grinding chamber (10b; 10c; 10d).
6. Agitator ball mill according to anyone of claims 1 or 3-5, characterised in that the exit end of the gas exhaust channel (120d) is connected to a vacuum container (2) and/or a vacuum pump (3).
7. Agitator ball mill according to anyone of the preceding claims, characterised in that the agitator (13b; 13c; 13d) comprises a shaft (130b; 130c; 130d) on which paddle wheels, discs or pins are fixedly mounted as stirring means (131b; 131c; 131d).

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