DE19940521C2 - mixing kneader - Google Patents

Abstract

The mixing bar (23.3,23.5) on one of the shafts (5/6) engages with one end in the plane (E) of the support elements (24,25,35) in the other shaft (6/5) where at least one supporting element (24/25,35) forms a recess (26,26.1) in the region of the path of the mixing bar (23.3,23.5). The mixer for mechanical, chemical and/or thermal process has two axially parallel, rotating shaft (5,6) in a housing with inner wall (31). The mixing bars (23-23.6) that are formed in the rotation direction and in the axial direction of the shaft run along the inner wall (31) of the housing and in the direction of the shaft or diagonal to the direction of the shaft (5,6) are located on a support element (22,24,25,34,36). The paths of the bars and the support element partially overlap on both shafts, and on turning the bars engages one of the shafts (5 or 6) between the support elements (22,24,25,34,36) on the other shaft (6 or 5).

Description

The invention relates to a mixer kneader for implementation of mechanical, chemical and / or thermal processes with at least two axially rotating shafts in a housing with an inner wall, the Shafts in the direction of rotation and in the axial direction of the shafts successive, along the inner wall of the housing and in the direction of the waves or at an angle to it Kneading bars are on a support element, the Paths of the kneading bars or support elements on the two Waves at least partially overlap and when rotating the Kneading bars on one shaft between the support elements grab the other wave and the at least one kneading bar on one wave with one end in the plane of Carrying elements engages on the other shaft.  

In many industrial areas, but especially in the chemical industry, products must be treated today become. For example, in one described above Mixing kneader two chemical products so intimately with each other are mixed up that they are at least partially with each other react. These products can be any Go through physical state, so that mechanical Requirements for a mixer kneader are very high.

Essentially, single-shaft and double-shaft Mixing kneaders distinguished. The present invention relates to a twin-screw kneader, such as that in CH 506 322 is described. Are on there a shaft radial disc elements and between the Disc-arranged, axially aligned kneading bars. Between these disks reach from the other shaft frame-shaped kneading elements. These kneading elements clean the discs and kneading bars of the first shaft. The Kneading bars on both shafts in turn clean the Housing inner wall.

Further embodiments of twin-screw mixers are described in EP 0 517 068 A1.

All these twin-shaft mixing and kneading mixers work among other things, to cover all areas with the treating product come into contact, and in particular the heated surfaces, which are mainly the inner jacket, Shaft and support element, from incrustations or - rid of attachments. At the above European Patent application EP 0 517 068 A1 already does this in largely, but remains as a result of kinematic reasons necessary gap between the kneading and transport elements on the inside wall of the housing Stand ring that is not cleaned.  

A mixing kneader is known from FR 2 090 808, in which Disc elements sit on each shaft, one inside the other comb. On the outer periphery there are two diametrically opposing kneading bars running parallel to the axis, which when turning in each also diametrically opposite recesses of the disc elements drive in and out again. Operation of this Mixing kneader only works if the shafts have the same Speed and run in opposite directions.

A mixer kneader of the type mentioned above is from DE 195 36 944 A1 known. There are kneading bars on one shaft, the one end in the plane of support elements on the engage another shaft.

The present invention is based on the object Internal cleaning of a mixer kneader with improved To further improve heat transfer.

To solve this problem, the waves turn in the same direction and at the same speed and at least one disk-shaped support element in the area of Path of the at least one kneading bar a recess formed.

Advantageous refinements are in the subclaims reproduced the invention.

This configuration ensures that the Kneading bar, which passes through the recess, the level the support elements overlap and thus stick a ring products left on the inside of the case for everyone Rotation of the shaft cleans. This ensures that the entire inner wall of the case in regular Intervals of incrustations or the like is exempt.  

The support element is a disk-shaped one Element on whose periphery the kneading bars are placed are. It is once provided that the disk-shaped Element through a recess in two pane parts is divided, the recess being designed so that the kneading bars of the other shaft through the recess can drive through. The larger part of the disc is preferably placed directly on the shaft during the smaller part of the pane over a cranked gusset the shaft is connected. This cranked gusset forms again a recess through which a kneading bar can drive another wave.

It is also conceivable that the disc-shaped element consists of two There are disks that lie on top of each other. It overlaps one disc the other to form the above Recess. Both disks can also be preferred overlap each other, so not from a disc a product ring remains uncleaned on the inner wall. In this case the disks are preferred mirrored, trimmed like a circular arc, with the the corresponding circular arc has a larger radius, than the disc itself.

Further advantages, features and details of the invention emerge from the description below more preferred Exemplary embodiments and with reference to the drawing; this shows in:

Figure 1 is a plan view of an inventive mixer kneader with a partially cut housing.

FIG. 2 shows a partially shown longitudinal section through the mixer kneader according to FIG. 1;

. Fig. 3 is a cross section through a shaft of the mixing kneader according to Figure 2 along line III-III in accordance with the handling of Fig. 4;

Fig. 4 is a developed view of the shaft of the mixing kneader according to FIG. 2;

Fig. 5 is a partial longitudinal-section through a further embodiment of a mixing kneader;

Fig. 6 shows a cross section through a shaft of the mixing kneader according to FIG 5 along line VI-VI in accordance with the processing in Fig. 7.

Fig. 7 is a developed view of the two shafts of the mixing kneader according to Fig. 5.

A mixer kneader P has a housing according to FIG. 1, which can consist of several housing sections 1 a, 1 b and 1 c. The housing sections are coupled to one another by corresponding flange connections 2 . In the housing section 1 a there is a feed nozzle 3 for a product to be treated in the mixing kneader and in the housing section 1 c an outlet nozzle 4 for the treated product.

The product is transported from the feed nozzle 3 to the outlet nozzle 4 by means of two shafts 5 and 6 and kneading and transport elements 7 arranged thereon. During transport, the product is mixed and kneaded, and preferably a thermal treatment takes place. For this purpose, the shafts 5 and 6 and optionally also the kneading and transport elements 7 and, not shown in more detail, the housing wall 8 are heated. For introducing a heating medium into the shafts 5 and 6 and from there possibly into the interior of the kneading and transport elements 7 , connections 9 and 10 are arranged around corresponding inlet and outlet nipples 11 and 12 for the heating medium guided through the shafts 5 and 6 . Appropriate routing of the heating medium in the lateral surfaces of the shafts 5 and 6 and a corresponding return through the outlet connection 12 are state of the art and are therefore not described further.

Between the terminals 9 and 10 extend through the shafts 5 and 6 connected to shaft journals 13 and 14, a lantern 15, wherein against the housing 1 are each a stuffing box 16 and 17 for sealing the shaft 5 and 6 are provided. The shaft journals 13 and 14 are coupled to one another outside the lantern via a corresponding synchronization gear with the gears 18 and 19 , the synchronization gear being connected to a drive 21 via a belt drive 20 . Via this drive 21 and the belt drive 20 , the gears 18 and 19 are rotated, which are transmitted to the shaft 5 and 6 , respectively. This rotary motion is transmitted to the shafts 5 and 6 in the same direction at the same speed. Corresponding synchronization gears are state of the art and should not be described in more detail here.

According to FIG. 2, each kneading and transport element 7 on a supporting member 22, and a kneading bar 23rd According to FIG. 3, the support element is designed in the form of a disk, the kneading bars sitting on the periphery of the disk-shaped support elements.

The disk-shaped support element is divided into a larger and a smaller disk part 24 and 25 . Both disk parts lie in the same plane and are preferably the outer surfaces at the same radius r which rotates about a central axis M of the shaft 5/6. The larger disk part 24 and the smaller disk part 25 are separated by a recess 26 , the larger disk part 24 toward the recess 26 having an arcuate section 27 with a larger radius than the radius r.

The smaller disk part 25 , which still has two kneading bars 23.1 and 23.2 on its periphery, has a straight edge 28 towards the recess 26 . It is connected to the shaft 5/6 via an axially offset gusset 29th

The recess 26 is arranged and designed such that a kneading bar 23.3 can pass through it when the shafts 5 and 6 are rotated. For this purpose, the kneading bars is 23.3 formed extended on one side, so that it with this extended end 30 in a plane E engages, which is / are formed upon rotation of the shafts 5 6 of the successive support elements in the rotational direction 22nd

Another kneading and transport element in the axial direction of the shaft, on the other hand, has a kneading bar 23.4 which has a shortened end 32 toward the gusset 29 .

From the settlement of both shafts 5/6 of FIG. 4 shows that the greater disc portions 24 and the smaller disc portions 25 of the two shafts 5/6 mesh with each other. The smaller disc portions 25 are arranged respectively on the shaft 5 added / 6 from each other, is provided so that every third consecutive in the axial direction disc-shaped support element in each case a smaller disc part 25th Each disk-shaped support element has only one kneading bar 23.3 with an elongated end and one kneading bar 23.4 with a shortened end in the direction of rotation.

As clearly evident in the processing of FIG. 4, an entire inner wall 21 of the housing 8 coated by the kneading bars by this configuration, since the extended end 30 of the kneading bar 23.3 sweeps especially those gaps 33, which are formed of the normal kneading bars 23 ,

In another embodiment according to FIGS. 5 to 7, the kneading and transport element is formed by two disks 34 and 35 which lie one on top of the other. Preferably, both disks have 34 and 35 a same radius r around the center of the shaft 5/6 and have a mirror image opposite circular-arc portion 27 having a larger radius r than the radius. This circular arc section 27 thus runs close to the shaft surface and, as can be seen in FIG. 6, leaves a surface area 36 of the disk 34 free, so that a recess 26.1 is formed thereby, which can be coated by an extended end 30.1 of a kneading bar 23.5 . A radially projecting wing 37 is even formed on this extended end 30.1 , with which at least a part of the free surface 36 can be cleaned.

If the kneading bars 23.5 are axially in a row, as in the present exemplary embodiment, then the kneading bars 23.5 have both the one-side extended and the shortened end, ie the kneading bar 23.5 is axially offset from the other kneading bars.

In the development according to FIG. 7 and here in particular in the upper part, it can be seen how the kneading and transport elements interlock. The kneading bars as a whole are positioned at an angle to the longitudinal axis of the shaft. The kneading bars 23.5 , which, in contrast to the other kneading bars 23, have the elongated end 30.1 or are offset to the right, lie on a line which runs obliquely to the axial direction. The same also applies to kneading bars 23.6 which are arranged offset to the left.

Position Number List

1

housing section

2

flange

3

feeding connection

4

outlet

5

wave

6

wave

7

Kneading and transport element

8th

housing

9

connection

10

connection

11

inlet nipple

12

outlet nipple

13

shaft journal

14

shaft journal

15

Lantern

16

gland

17

gland

18

gear

19

gear

20

belt drive

21

drive

22

carrying member

23

kneading

24

larger pane part

25

smaller pane part

26

recess

27

Arc section

28

edge

29

gore

30

The End

31

interior walls

32

shortened end

33

gap

34

disc

35

disc

36

area

37

wing
E level
M central axis
P mixer kneader
r radius

Claims (8)

1. Mixing kneader for performing mechanical, chemical and / or thermal processes with at least two axially parallel rotating shafts ( 5 , 6 ) in a housing with an inner wall ( 31 ), with the shafts ( 5 , 6 ) in the direction of rotation and in the axial direction the shafts ( 5 , 6 ) successive kneading bars ( 23-23.6 ) running along the inner wall ( 31 ) of the housing and in the direction of the shafts ( 5 , 6 ) or obliquely thereto on a support element ( 22 , 24 , 25 , 34 , 36 ), the paths of the kneading bars ( 23-23.6 ) or support elements ( 22 , 24 , 25 , 34 , 36 ) on the two shafts ( 5 , 6 ) at least partially overlap and the kneading bars ( 23-23.6 ) on one shaft ( 5 or 6 ) between the support elements ( 22 , 24 , 25 , 34 , 36 ) on the other shaft ( 6 or 5 ) and the at least one kneading bar ( 23.3 , 23.5 ) on one shaft (5/6) with one end (30, 30.1), in the plane (e) of supporting elements (24, 25, 34 Engages 35) on the other shaft (6/5), characterized in that the shafts (5, 6) rotate in the same direction and at the same speed and at least a disk-shaped supporting element (24/25, 34, 35) in the region of the path of at least a kneading bar ( 23.3 , 23.5 ) forms a recess ( 26 , 26.1 ). 2. The mixing kneader according to claim 1, characterized in that the supporting element for the kneading bars (23.3, 23.4) is a disc (24/25) which in the region of the path of with their meshing kneading bar (23.3) of the other shaft (5/6 ) has a recess ( 26 ). 3. Mixing kneader according to claim 2, characterized in that the disc is divided into two and is separated by the recess ( 26 ). 4. The mixing kneader according to claim 3, characterized in that a smaller disc part (25) is connected via an angled gusset (29) to the shaft (5/6). 5. Mixing kneader according to claim 3 or 4, characterized in that a larger disc part ( 24 ) is trimmed like a circular arc to form a circular arc ( 27 ) with a larger radius. 6. Mixing kneader according to claim 1, characterized in that two disks ( 34 , 35 ) lie one on top of the other, at least one disk ( 34 ) overlapping the other to form the recess. 7. Mixing kneader according to claim 6, characterized in that the two disks ( 34 , 35 ) overlap one another. 8. Mixing kneader according to claim 6 or 7, characterized in that the disc ( 35 ) is trimmed like a circular arc to form a circular arc ( 27 ) with a larger radius.