EP0913200A1 - Agitator mill - Google Patents

Abstract

Milling vessel (3) is fitted with cylindrical bowl-shaped rotor (42) forming an annular milling chamber (9'') as milling gap with an inner stator (24) and an outer milling chamber (9') is formed between the inner wall (10) of the vessel and an outer wall (43) of the rotor. Cross sectional area of the outer milling chamber is substantially larger than that of the inner milling chamber. Inner wall (44) of the rotor and the outer wall (26) of the stator are smooth.

Description

The invention relates to an agitator mill according to the preamble of the claim 1.

Such an agitator mill is known from EP 0 370 022 B (corresponding to US patent 5 062 577). In this known agitator mill are on the boundary walls of the outside grinding room and at least on the inner boundary wall of the inner grinding chamber, peg-shaped stirring tools attached by which a mutual acceleration and Braking of the auxiliary grinding bodies takes place, which leads to a turbulent flow state with a grinding and dispersing effect mainly through Impact effects leads. The regrind flows through a regrind feed chamber, through a transition area past the overflow channels into the outside grinding chamber and through the deflection chamber into the inner grinding chamber. The Auxiliary grinding bodies run in a circle through the outside grinding area, the deflection area, the inside grinding chamber and the overflow channels back into the outside grinding chamber or in the transition area leading into this. The Grist flows from the end of the inner grinding chamber to the separator. The The separating device is not used to any significant extent for separating Auxiliary grinding bodies on the one hand and regrind on the other; anyway - too in this application - the term separator is used because it is generally prevailed in the technical language. As can be seen from the above Explanation shows, the separation of the auxiliary grinding bodies from Grist already in front of the separator. The well-known agitator mill has proven itself extremely well in practice.

From DE 28 11 899 C an agitator mill is known, the outside grinding area on the one hand and the inside grinding chamber on the other hand each frustoconical rejuvenate, i.e. the cross section of the grinding room is on everyone Conical side of the central longitudinal axis of the rotor and stator. The Grist flows through the agitator mill from the inside out, i.e. it flows into the narrow diameter of the inner grinding chamber, flows through it then the radially expanding inner grinding chamber, the deflection chamber and then the radially widening outside grinding room. From there it flows radially inwards through a one-sided boundary of the agitator Space to a separator through which the regrind is discharged becomes. The entry of an overflow channel is arranged downstream of this separating device, the inlet of which is arranged radially inside the separating device, So this is subordinate. From there, the grinding aids flow through Overflow channels in the rotor in the initial area of the inner grinding chamber. The boundary walls of the grinding chamber are smooth-walled. The width of the grinding gap, i.e. the radial width of the grinding chamber is constant; the distance to However, the axis of rotation increases steadily. It follows from this that the shear gradient increases over the path of the regrind from the inside to the outside. this leads to to the fact that it is either too low in the inside grinding room or in the outside grinding room is too high, which leads to an uneven loading of the Grist leads. (The shear gradient is defined as the quotient of speed the rotating surface and gap width.)

In the unpublished DE 196 32 757.1 A1 (corresponding to US serial No. 08/906 043) is known from an obvious prior use agitator mill shown and described, its outside grinding room and the inner grinding chamber are designed as a grinding gap. This Grinding gaps are smooth-walled and free of stirring tools. Due to the smooth-walled design of the cylindrical boundary walls a flow is generated from the outside grinding chamber and inside grinding chamber, in which the grinding aid body moves in layers relative to each other become. The shear gradient and thus the local stress intensity is in the outside grinding room on the one hand and in the inside grinding room on the other constant above the respective grinding chamber height.

From DE 38 44 380 C1 an agitator mill is known, the one Has agitator shaft with a cage which is part of the agitator shaft. The cage is attached to a support part between and the lid of the grinding container and an adjacent area of the inner wall of the grinding container a friction gap is formed. The regrind is in this friction gap by friction of the walls of the grinding container delimiting these friction gaps and the agitator shaft activated.

The invention is based, an agitator mill of the generic type Kind to design so that on the one hand an intensive shredding and dispersing the regrind particles is maintained that the comminuted Grist particles but get a finely smoothed surface.

This object is achieved by the features in the labeling part of claim 1 solved. In the outside grinding room - as with the generic agitator mill - an intensive grinding and Dispersion of the regrind particles mainly through impact effects an impact grinding. The dwell time of the material to be ground is in the outside grinding room - Compared to the time spent in the interior grinding room - very high. In the indoor grinding room on the other hand, there is smoothing, i. H. a kind of surface polishing the regrind particles newly created in the outside grinding chamber by crushing, a polishing grinding. When passing from the outside grinding room There is sufficient acceleration in the interior grinding chamber of the regrind. Claim 2 specifies how this acceleration can be optimized.

Claims 3 and 4 give preferred lower ranges for the ratio of the cross-sectional areas of the outside grinding area and inside grinding area. Claims 5 and 6 give preferred upper limits for the ratio the cross-sectional areas of the outside grinding chamber and inside grinding chamber on.

In claims 7 to 10 are preferred limits for the radial Width of outside grinding room and inside grinding room specified.

Claim 11 reflects measures by which the impact grinding in the outer grinding chamber can be optimized.

The claims 12 to 16 indicate a further embodiment in which the Grist before entering the outer grinding area of a predispersion is subjected to a narrow annular cylindrical vortex. This Effect is brought about in particular by the fact that the ring-cylindrical Vortex gap a very small extension radial to the central longitudinal axis and that the overflow channels enter this vortex gap, so that alternating wall sections of the rotor delimiting the vortex gap and the outlet openings of the overflow channels on the inner wall of the Run past the grinding container.

Fig. 1

eine schematische Darstellung einer Rührwerksmühle in einer Seitenansicht,

Fig. 2

einen Längsschnitt durch den Mahlbehälter der Rührwerksmühle und

Fig. 3

einen Längsschnitt durch den Mahlbehälter einer abgewandelten Ausführungsform der Rührwerksmühle

Further features, advantages and details of the invention result from the following description of an embodiment of the invention with reference to the drawing. It shows:

Fig. 1

1 shows a schematic illustration of an agitator mill in a side view,

Fig. 2

a longitudinal section through the grinding container of the agitator mill and

Fig. 3

a longitudinal section through the grinding container of a modified embodiment of the agitator mill

The agitator mill shown in Fig. 1 has in the usual way Stand 1 on which a cylindrical grinding container 3 can be attached. In the stand 1 is an electric drive motor 4 housed with a V-belt pulley 5 is provided, one of which via V-belt 6 a drive shaft 7 rotatably connected V-belt pulley 8 rotating is drivable.

As can be seen in particular from FIG. 2, the grinding container 3 consists of a cylindrical, a grinding chamber 9 surrounding inner wall 10, the a substantially cylindrical outer shell 11 is surrounded. Of the Inner cylinder 10 and the outer jacket 11 delimit one between them Cooling room 12. The lower end of the grinding chamber 9 is an annular Base plate 13 formed on the grinding container by means of screws 14 is attached.

The grinding container 3 has an upper ring flange 15, by means of which it is fastened to the underside of a support housing 16 by means of screws 17, which is attached to stand 1 of the agitator mill. The grinding chamber 9 is closed by a lid 18. The support housing 16 has a medium Bearing and seal housing 19, which is coaxial to the central longitudinal axis 20 of the grinding container 3 is arranged. This seal housing 19th is driven by the drive shaft 7, which also runs coaxially to the axis 20 enforced, on which an agitator 21 is attached. In the grinding room 9 adjacent area of the seal housing 19 opens a regrind feed line 22 a.

On the circular base plate 13 is a protruding into the grinding chamber 9, approximately cup-shaped, cylindrical inner stator 24 fastened, that from a grinding chamber 9 delimiting, coaxial to axis 20, cylindrical outer jacket 26 and a coaxial to the axis 20, cylindrical inner shell 27 there. Outer jacket 26 and inner jacket 27 delimit a cooling space 28 between them. The cooling space 28 is connected to a cooling space 29 in the base plate 13, the cooling water is supplied via a cooling water supply nozzle 30 which via an outlet pipe 30a is discharged. The cooling chamber 12 of the grinding container 3, cooling water is supplied via a cooling water supply nozzle 31, which is discharged via a cooling water discharge nozzle 32.

On the upper face 33 of the grinding chamber 9 located above Inner stator 24 is a grinding material-grinding body separating device 34 is arranged, which is connected to a regrind drain line 35. Between the separating device 34 and the drain line 35 is a regrind collecting funnel 36 provided. The drain line 35 is in the range of Base plate 13 provided with a bracket 38, which by means of screws 39 with the base plate 13 or the inner stator fixedly connected to it 24 is releasably connected. The separating device 34 is opposite to the annular end face 33 of the inner stator 24 by means of a seal 40 sealed and after loosening the screws 39 together with the Drain line 35 and the collecting funnel 36 from the inner stator 24 after pulled out below. The separator 34 can thus from the Grinding chamber 9 are pulled out without the located in it Grinding auxiliary body 41 must be removed from the grinding chamber, since the Filling the grinding chamber 9 with these auxiliary grinding bodies 41 when not driven Agitator 21 does not reach the front side 33.

The basic structure of the agitator 21 is pot-shaped, i.e. it shows one essentially ring-cylindrical rotor 42 by a cylindrical Outer wall 43 and a coaxial to this and coaxial to the axis 20 cylindrical inner wall 44 is formed. Between the outer wall 43 and the inner wall 44 of the rotor 42, a cooling space 45 is formed. The rotor 42 is attached to a rotor support member 46 which is connected to the Wave 7 is connected. The supply and discharge of cooling water to the cold room 45 takes place via in the shaft 7 and formed in the rotor support member 46 Cooling water channels 47, 48. Through the smooth-walled inner cylinder 10 of the Grinding container 3 and the smooth-walled cylindrical outer wall 43 of the rotor 42 on the one hand and through the cylindrical smooth-walled inner wall 44 of the rotor 42 and the cylindrical smooth-walled outer jacket 26 of the Inner stator 24, on the other hand, the grinding chamber 9 is in a cylindrical ring Outside grinding chamber 9 'on the one hand and a cylindrical ring Interior grinding chamber 9 '', on the other hand, divided by a deflection chamber 49 are connected to one another in the area of the base plate 13.

On the formed by the inner cylinder 10 and the outer wall 43 Grinding chamber boundary walls protrude into the outer grinding chamber 9 ' stationary stirring tools 50 or stirring tools rotatable with the rotor 42 51 attached. On the through the inner wall 44 and the outer jacket By contrast, the 26 grinding chamber boundary walls formed are none attached to the inner grinding chamber 9 '' projecting stirring tools. The ground material flows through the grinding chamber 9 in accordance with the flow direction arrows 52 coming from the regrind feed line 22 a regrind feed space 53 between the rotor support part 46 on the one hand and the cover 18 and the adjacent area of the inner wall 10 on the other hand, down through the outer grinding chamber 9 ', through the deflection chamber 49 radially inwards and from there through the inner grinding chamber 9 '' up to the separator 34. On the way through the outside grinding room 9 ', the deflection chamber 49 and the inner grinding chamber 9' 'will Regrind with rotating driven agitator 21 in cooperation with the grinding auxiliary bodies 41 processed. The ground material leaves the grinding chamber 9 through the separator 34, from where it goes through the regrind drain line 35 flows off.

The separating device used to separate auxiliary grinding bodies 41 34 is arranged in a cylindrical recess 54 of the rotor support part 46. Between the cylindrical wall 55 of the recess 54 and the Separating device 34 are elongated on wall 55 in cross section about triangular driver 56 attached, each between them in cross section approximately funnel-shaped inlet areas for overflow channels 57 form. Such a configuration with such drivers 56 is out EP 0 439 826 B (corresponds to US Pat. No. 5,133,508).

The overflow channels 57 are located in the rotor support part 46, specifically in the Transition area of the rotor support member 46 to the cylindrical rotor 42 and - in Direction of flow direction arrows 52 seen - in front of the separator 34. They connect - based on the flow direction accordingly flow direction arrows 52 - the end of the interior grinding chamber 9 '' with the beginning of the outside grinding chamber 9 ', i.e. with a transition area 58 of the regrind feed space 53, which enters the outer grinding space 9 ' transforms. The overflow channels 57 run in relation to the direction of rotation 59 of the agitator 21 - radially from the inside outward against the Direction of rotation 59, so that in the inner grinding chamber 9 ″ with a centrifugal acceleration provided auxiliary grinding body 41 through the overflow channels 57 thrown off and thus brought back into the regrind feed space 53 become.

The outer grinding chamber 9 ', with the stirring tools 51 attached to the rotor 42 and the stationary counter-stirring tools 50 attached to the grinding container 3, is a real grinding chamber in which the auxiliary grinding bodies 41 are subjected to an intensive pulse exchange with the rotating stirring tools 51 and the stationary stirring tools 50 in which the regrind is subjected to an intensive shearing and dispersing process by impact effects. In the outer grinding chamber 9 ', the individual particles of the grinding stock supplied in the form of a dispersion or suspension are intensively comminuted. In contrast, the inner grinding chamber 9 ″ is designed as a grinding gap, the cross-sectional area of which is considerably smaller than the cross-sectional surface of the outer grinding chamber 9 ′. The outer grinding chamber 9 'has an outer diameter Da and an inner diameter Di. The inner grinding space 9 ″ designed as a grinding gap has an outer diameter da and an inner diameter di. The following applies to the ratio of the cross-sectional areas of the outer grinding chamber 9 'and the inner grinding chamber 9'' 4 ≤ (Da 2nd - Tue 2nd ) / (there 2nd - di 2nd ) and preferred 5 ≤ (Da 2nd - Tue 2nd ) / (there 2nd - di 2nd ) . In other words, this means that the cross-sectional area of the outer grinding chamber 9 'is 4 or 5 times larger than the cross-sectional area of the inner grinding chamber 9''. The consequence of this configuration is that the flow rate of the material to be ground in the inner grinding chamber 9 ″ is at least 4 or 5 times greater than in the outer grinding chamber. The residence time of the material to be ground in the outer grinding chamber 9 'is correspondingly approximately 4 or 5 times greater than the residence time of the material to be ground in the inner grinding chamber 9''which is designed as a grinding gap.

The following values have emerged as upper limit values for the ratio of the cross-sectional areas of the outer grinding chamber 9 'and the inner grinding chamber 9'': (There 2nd - Tue 2nd ) / (there 2nd - di 2nd ) ≤ 30 and preferred (There 2nd - Tue 2nd ) / (there 2nd - di 2nd ) ≤ 25 .

The same applies to the width a of the outer grinding chamber 9 'radially to the axis 20 15 mm ≤ a. The upper limit is a ≤ 300 mm. For the gap width b des Internal grinding chamber, also radial to axis 20, applies 3 mm ≤ b. As the top Limit applies b ≤ 15 mm. It applies that the gap width b at least in each case correspond to 4 times the diameter c of the auxiliary grinding bodies 41 should. The upper limit for the diameter c of the auxiliary grinding body 41 is: c ≤ 1.5 mm.

So that the extraordinary acceleration of the regrind when crossing from the outside grinding chamber 9 'to the inside grinding chamber designed as a grinding gap 9 '' is possible, the deflection chamber 49 is oriented towards the inner grinding chamber provided continuously tapering acceleration section 60, which works like a nozzle.

While in the outer grinding chamber 9 'a turbulent grinding process to a high degree takes place due to the smooth-walled design of the cylindrical Boundary walls of the inner grinding chamber 9 '' there a flow generated in which the grinding aid body 41 moves in layers relative to each other become. The shear gradient and thus the local stress intensity is constant in the interior grinding chamber 9 '' above its height. Because of the short dwell time of the material to be ground in the inner grinding chamber 9 ″ and the layered relative movement of the auxiliary grinding bodies 41 does not take place more intensive dispersing and crushing instead of just a load of possibly hatched coarse particles or overall a rounding and surface treatment of the outside grinding room 9 'newly created particle surfaces instead. So it finds one Type polishing of the individual regrind particles instead.

The agitator mill described can be arranged vertically or horizontally are, as described - a vertical central longitudinal axis 20 or have a corresponding horizontally arranged central longitudinal axis. Especially with a horizontal arrangement of the agitator mill the drivers 56 are not required. Otherwise, of course further constructive adjustment measures may be necessary.

The embodiment according to FIG. 3 differs from that according to FIG. 2 only by the configuration of the cylindrical peripheral wall 61 of the rotor support part 46 'of the rotor 42'. Between this peripheral wall 61 and the the associated inner wall 10 of the grinding container 3 is a swirl gap 62 formed into the frustoconical area of the regrind feed space 53 flows into. The overflow channels 57 'open into the vortex gap 62 a. At the transition 58 of the rotor support part 46 'are the overflow channels 57 'completed with a boundary 63, so that the auxiliary grinding bodies 41 in the transition area 58 not directly into the outside grinding area 9 ', but can only enter the swirl gap 62.

The gap width e of the swirl gap 62 radially to the central longitudinal axis 20 is very small. The following applies:
3 mm ≤ e ≤ 8 mm
and particularly
4 mm ≤ e ≤ 5 mm.
The grinding auxiliary body 41 also applies to the ratio of the gap width e to the diameter c
3 c ≤ e ≤ 4 c.

Since the vortex gap 62 is very much in relation to the outer grinding chamber 9 ' has a narrow cross-section, the flow rate of the ground material is Vortex gap 62 in the direction of the outer grinding chamber 9 'is very high, so that a Escape of grinding aids 41 in the frustoconical area of the regrind feed space 53 is excluded. In particular, that those interrupted by the respective outlet 64 of the overflow channels 57 ' Wall sections 65 of the circumferential wall 61 with the as it were an overflow channels 57 'forming a recess will alternate an extremely intensive swirling of the auxiliary grinding body 41 achieves what for an extremely intensive predispersion of the ground material in the Vortex gap 62 leads. This configuration makes one extremely effective series connection of predispersion, impact grinding and polishing grinding of the ground material.

Claims (16)

Agitator mill for treating flowable regrind, with a grinding vessel (3) which delimits a largely closed grinding chamber (9) with an inner wall (10) and a stirrer arranged in a pot-shaped manner relative to a common central longitudinal axis (20) ( 21) with an annular cylindrical rotor (42, 42 ') within which an inner stator (24) fixedly connected to the grinding container (3) is arranged, between the inner wall (10) of the grinding container (3) and an outer wall (43) of the rotor (42, 42 ') an annular cylindrical outer grinding chamber (9') and between an inner wall (44) of the rotor (42, 42 ') and an outer jacket (26) of the inner stator (24) a coaxially inside the outer grinding chamber (9 ') arranged and connected to it via a deflection chamber (49) is an annular cylindrical inner grinding chamber (9''), projecting into the outer grinding chamber (9,) on the outer wall (43) of the rotor (42, 42') Stirring tools (51) attached The outer grinding chamber (9 '), the deflection chamber (49) and the inner grinding chamber (9'') form the grinding chamber (9) partially filled with auxiliary grinding bodies (41), one of which is the outer grinding chamber (9' ) upstream and in this in the flow direction (52) of the millbase feed space (53) and a downstream of the inner grinding chamber (9 '') in the flow direction (52) of the millbase separation device (34) for passage of the millbase approximately on the same side of the grinding container (3) are arranged and wherein in the agitator (21) overflow channels (57, 57 ') for returning the auxiliary grinding bodies (41) from the area of the separating device (34) into the area of the grinding stock feed space (53) are provided connect the end of the inner grinding chamber (9 '') to the beginning of the outer grinding chamber (9 '),
characterized, that the inner grinding chamber (9 ',) is designed in the form of an annular gap as a grinding gap, that the cross-sectional area of the outer grinding chamber (9 ') is considerably larger than the cross-sectional area of the inner grinding chamber (9'') and that the inner wall (44) of the rotor (42, 42 ') and the outer wall (26) of the inner stator (24) are smooth-walled, free of stirring tools. Agitator mill according to claim 1, characterized in that - based on the direction of flow (52) of the material to be ground - between the outer grinding chamber (9 ') and the inner grinding chamber (9'') a continuously tapering acceleration section (60) towards the inner grinding chamber (9'') for the Regrind is provided. Agitator mill according to claim 1 or 2, characterized in that that for the ratio of the cross-sectional area of the outer grinding chamber (9 ') to the cross-sectional area of the inner grinding chamber (9''):
4 ≤ (Da 2nd - Tue 2nd ) / (there 2nd - di 2nd ) , in which Da = the outside diameter of the outside grinding chamber (9 '), Di = the inner diameter of the outer grinding chamber (9 '), da = the outside diameter of the inside grinding chamber (9 '') and di = the inside diameter of the inside grinding chamber (9 '') is. Agitator mill according to claim 3, characterized in that for the ratio of the cross-sectional area of the outer grinding chamber (9 ') to the cross-sectional area of the inner grinding chamber (9''):
5 ≤ (Da 2nd - Tue 2nd ) / (there 2nd - di 2nd ) , in which Da = the outside diameter of the outside grinding chamber (9 '), Di = the inner diameter of the outer grinding chamber (9 '), da = the outside diameter of the inside grinding chamber (9 '') and di = the inside diameter of the inside grinding chamber (9 '') is. Agitator mill according to one of claims 1 to 4, characterized in that for the ratio of the cross-sectional area of the outer grinding chamber (9 ') to the cross-sectional area of the inner grinding chamber (9''):
(There 2nd - Tue 2nd ) / (there 2nd - di 2nd ) ≤ 30 , in which Da = the outside diameter of the outside grinding chamber (9 '), Di = the inner diameter of the outer grinding chamber (9 '), da = the outside diameter of the inside grinding chamber (9 '') and di = the inside diameter of the inside grinding chamber (9 '') is. Agitator mill according to claim 5, characterized in that for the ratio of the cross-sectional area of the outer grinding chamber (9 ') to the cross-sectional area of the inner grinding chamber (9''):
(There 2nd - Tue 2nd ) / (there 2nd - di 2nd ) ≤ 25 , in which Da = the outside diameter of the outside grinding chamber (9 '), Di = the inner diameter of the outer grinding chamber (9 '), da = the outside diameter of the inside grinding chamber (9 '') and di = the inside diameter of the inside grinding chamber (9 '') is. Agitator mill according to one of claims 1 to 6, characterized in that that the following applies to the width a of the outer grinding chamber (9 '):
15 mm ≤ a. Agitator mill according to one of claims 1 to 7, characterized in that the following applies to the width a of the outer grinding chamber (9 '):
a ≤ 300 mm. Agitator mill according to one of claims 1 to 8, characterized in the following applies to the gap width b of the inner grinding chamber (9 ''):
3 mm ≤ b. Agitator mill according to one of claims 1 to 9, characterized in that the following applies to the gap width b of the inner grinding chamber (9 ''):
b ≤ 15 mm. Agitator mill according to one of claims 1 to 10, characterized in that on the inner wall (10) of the grinding container (3) in the outer grinding chamber (9 ') projecting stationary stirring tools (50) are attached. Agitator mill according to one of claims 1 to 11, characterized in that that between the regrind supply space (53) and the outer grinding space (9 ') is formed by the rotor (42') and the inner wall (10) of the grinding container (3) limited annular cylindrical swirl gap (62) in which the overflow channels (57 ') open with exits (64). Agitator mill according to claim 12, characterized in that the rotor (42 ') delimits the vortex gap (62) with a cylindrical peripheral wall (61) in which the outlets (64) of the overflow channels (57') lie, the outlets (64) with wall sections (65) of the peripheral wall ( 61) alternate in the circumferential direction of the rotor (42 '). Agitator mill according to claim 12 or 13, characterized in that for the gap width e of the swirl gap (62) between the peripheral wall (61) and the inner wall (10) of the grinding container (3) radially to the central longitudinal axis (20) applies:
3 mm ≤ e ≤ 8 mm. Agitator mill according to claim 14, characterized in that that the following applies to the gap width e:
4 mm ≤ e ≤ 5 mm. Agitator mill according to claim 14, characterized in that that for the gap width e in relation to the diameter c the auxiliary grinding body (41) applies:
3 c ≤ e ≤ 4 c.

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