EP2424675B1 - Separator - Google Patents

Description

The invention relates to a separator according to the preamble of claim 1.

Generic separators are from the DE 195 08 334 A1 and the DD 288 322 A5 known.

Another such construction is from the DE-AS 1 141 951 known. This document shows a separator with a centrifugal drum into which a separating plate package is inserted, the separating plate package being divided into two separating plate package sections below and above this separating plate by a separating plate which has a larger diameter than the other separating plates. A product to be processed is fed through a feed in the drum shaft and enters the separation chamber via a distributor. There it in turn enters a riser channel of the separator plate package, which extends over the entire height of the separator plate package. The centrifugal material entering the separation chamber is freed from the main part of the sludge in the space below the separation plate, which forms a sludge cushion on the circumference of the separation chamber. The heavy liquid is prevented by the sludge pad from stepping around the outer edge of the larger diameter separating plate. The remaining light liquid is separated off and collected in the upper separator plate section. The separated heavy liquid is discharged from the separation chamber through a channel with a larger diameter and the separated light liquid through another channel with a smaller diameter of the centrifugal drum.

The position of the separation plate with a larger diameter can be varied depending on the application in the separation chamber. According to a preferred embodiment, it is approximately at the height of piston slide openings for discharging solid matter from the centrifugal drum.

The state of the art are still US 2,487,364 and the GB 206 723 as well as the US 50 52 996 A. and the US 993 791 A. called.

Starting from the prior art mentioned at the outset, the invention has the task of optimizing the separating and clarifying action in a simple manner compared to the generic centrifuge.

The invention solves this problem by the subject matter of claim 1.

By dividing the separating plate package into separating plate package sections, each of these sections can be optimally designed with regard to the respective task, for example with regard to the separating gap width or the separating plate and tab geometry.

It is expedient if the lower separating plate package section is designed as the separating device and the upper separating plate packet section as the clarifying device, in order first to separate the lighter liquid phase from the centrifuged material to be processed and to then separate the remaining solids in the separating plate packet section, which acts exclusively as a clarifying device.

In order to prevent backmixing with the lighter liquid phase in the separating plate package section, which acts exclusively as a clarifying device, it is particularly advantageous that the separating plate stack is sealed radially inwards in this area, which can be implemented in a variety of ways.

Advantageous refinements can be found in the remaining subclaims.

Figur 1

einen Schnitt durch einen Teilbereich einer Schleudertrommel eines erfindungsgemäßen Separators; und

Fig. 2a-d

schematisierte Schnittdarstellungen innerer Abschnitte von Trenntellerpakten zum Einbau in eine Schleudertrommel der Figur 1.

The invention is described in more detail below with reference to the drawing using an exemplary embodiment. It shows:

Figure 1

a section through a portion of a centrifugal drum of a separator according to the invention; and

2a-d

Schematic sectional views of inner sections of separating plate packs for installation in a centrifugal drum Figure 1 .

In the in Figure 1 The centrifugal drum 1 shown with the vertical axis of rotation D, a separating plate package 2 made up of a plurality of separating plates 3 is arranged concentrically to the axis of rotation D.

The separating plates 3 have a conical shape, are stacked axially one above the other and are spaced apart by means of spacers (tabs and the like), not shown here.

The separating plate package 2 is held directly or via a holder on a distributor shaft 4 of a distributor 5 which can be rotated during operation and is secured against rotation relative to the latter.

The separator plate package 2 has a lower separator plate section 6 made of stacked lower separator plates 3a and an upper separator plate section 7 made of upper separator plates 3b, the lower separator plate section 6 and the upper separator plate section 7 being provided with a separating plate 3c which has a larger diameter than the other separating plates 3a , 3b and here also a greater thickness or wall thickness are separated from one another in the axial direction. The lower separator plate section 6 is designed as a separating device for separating two liquid phases L1, L2 and the upper separating plate section 7 as a clarifying device for clarifying one of the liquid phases L2 from solids S.

In operation, the centrifuged material to be clarified - in particular milk - is fed into the rotating system through a central inlet pipe 8 which does not rotate during operation in the region of the distributor 5. The distributor 5 has distributor channels 9 which open below the corresponding riser channels 10 in the lower separating plate package section 6 into the separating space. The rising channels 10 lie on a first, inner radius R1.

In the lower separating plate package section 6, the two liquid phases L1, L2 of different specific weights are separated from one another (in the case of milk, cream L1 and skim milk L2).

The liquid phase L1 with the lower specific weight - in the case of milk, the cream - is guided inwards through a discharge channel 11 into a first peeling chamber (not shown here) and from there with a first peeling disc (not shown here) from the rotating system .

The liquid phase L2 with the higher specific weight - in the case of milk, the skimmed milk - on the other hand, is passed through one or more riser channels 14, which advantageously pass through the lower separator plate section 6, the separator plate 3c of larger diameter and the upper separator plate section 7. The one or more riser channels 14 in the upper separator plate section 7 lie on a larger radius R2 than the one or more riser channels 10 in the lower separator plate section 6.

In the upper separating plate package section 7, the liquid phase L2 - in the case of milk of skimmed milk - of solids is clarified.

The clarified skimmed milk L1 is passed through one or more discharge channels 15 passing through the upper separating plate package section 7 into a second peeling chamber (not shown here) and from there with a second peeling disc (not shown here) from the rotating system.

In contrast, the solids are discharged discontinuously through solids discharge openings 18, which are preceded by a piston valve 19.

Optionally, a further solid phase S can be discharged via a separating plate (not shown here) arranged vertically above the separating plate compact 2 through a third peeling chamber (not shown here) with a third peeling disc. An arrangement can also be used to control the piston slide 19 when no more liquid L2 is drained off through the third peeling disc then present.

The upper separating plate package section 7 has the special feature that the individual separating plates 3b of this separating plate package are sealed axially relative to one another in an area lying radially inward to the one or more discharge channels for the liquid phase L2 (as the clarified skimmed milk, if applicable), so that none Liquid can flow from the upper separating plate packet section 7 into the discharge channel 11 or pipes lying radially inside to the sealed area and thus into the first peeling chamber.

How out Fig. 2 can be seen, the sealing of the upper separator plate section 7 can take place radially inwards in various ways.

The 2a to 2d each show by way of example three separating plates 3b, each consisting of an inner separating plate section 30 which is oriented perpendicular to the axis of rotation D and an outer - conical - separating plate section 31 which encloses an angle α with the axis of rotation D.

According to a first variant, the separating plates 3b of the upper separating plate packet section 7 are sealed relative to one another in their radially inner separating plate section 30 by means of seals, in particular sealing rings 23 ( 2a to 2c ).

The seals can be in the form of flat seals 23a with a preferably rectangular cross section ( Fig. 2a ) be designed or as seals with a different, preferably round or elliptical cross-section ( 2b, 2c ).

The seals 23 are arranged in the plate gaps 25 between vertically adjacent separating plates 3b of the upper separating plate package section 7. They are preferably designed as circumferential sealing rings. However, it is also conceivable to arrange only ring segments as seals, for example, in the area between spacer plates of axially adjacent separating plates.

According to a preferred variant, a particularly good sealing effect is achieved in that the seals 23 are introduced in correspondingly shaped receiving grooves 24 which are formed in the separating plates. To Fig. 2b align these receiving grooves 24 in the vertical direction. To Fig. 2c on the other hand, provision is made for the receiving grooves (ring grooves) 24 to be radially offset from one another in vertically superimposed separating plates 3b, so that the seals in vertically successive separating plate gaps 25 between adjacent separating plates 3b each lie on different radii.

To Fig. 2d the sealing radially inwards is not achieved by separate seals, but rather in that the vertical adjacent separating plates are in each case directly adjacent to each other in sections, for example in a conical steep area 32 in which the conicity angle β is significantly smaller than the conicity angle α to the axis of rotation D. , so that the adjacent separating plates 3b touch each other directly in this area.

In the lower separator plate section 6, the separating gaps 25 between vertically adjacent separator plates 3a preferably have a smaller distance than in the upper separator plate section 7. <b><u> reference number <//></b> Centrifugal drum 1 Plate pack 2nd Plate 3, 3a, 3b, 3c Distribution body 4th Distributor 5 lower separator plate section 6 upper separator plate section 7 Inlet pipe 8th Distribution channel 9 Riser 10th Discharge channel 11 Risers 14 Drainage channels 15 Solid discharge openings 18th Spool 19th Seals 23 Gaskets 23a Grooves 24th Separation plate column 25th Separating plate sections 30, 31 Steep area 32 Radii R1, R2, Axis of rotation D Liquid phase L1, L2 Solid phase S

Claims (14)

1. Separator having a centrifugal drum (1) with a vertical rotational axis, in which a separator disk assembly (2) is arranged, which consists of a plurality of separator disks stacked one above the other (3) and is divided into a lower separator disk assembly section (6) and an upper separator disk assembly section (7), wherein

   a. the one lower separator disk assembly section (6) is designed as a separating device for separating an inflowing material to be centrifuged in the centrifugal field into two liquid phases (L1, L2) or as a combined separating and clarifying device for separating an inflowing material to be centrifuged in the centrifugal field into two liquid phases (L1, L2) and for clarifying a solid phase,

   b. the other upper separator disk assembly section (7) is designed as a clarifying device for clarifying a liquid phase to remove solids (S),
   characterized in that

   c. the upper separator disk assembly section (7), which acts as a clarifying device, is designed so as to be sealed radially inwards.
2. Separator according to claim 1, characterized in that the upper separator disk assembly section (7) is designed exclusively as a clarifying device.
3. Separator according to one of the preceding claims, characterized in that in the upper separator disk assembly section (7) acting as clarifying device, the separator disk gap (25) between vertically adjacent separator disks (3b) are sealed radially inwards by means of seals (23).
4. Separator according to one of the preceding claims, characterized in that the seals (23) are designed as circumferential sealing rings.
5. Separator according to claim 4, characterized in that the seals (23) are arranged in corresponding receiving grooves (24) in the separator disks.
6. Separator according to claim 5, characterized in that the seals (23) and/or the receiving grooves (24) of the upper separator disk assembly section (7) are aligned with one another in the vertical direction.
7. Separator according to claim 5, characterized in that the seals (23) and/or the receiving grooves (24) of the upper separator disk assembly section (7) are arranged offset to one another in the vertical direction.
8. Separator according to one of the preceding claims, characterized in that the seals (23) have a rectangular, oval or circular cross-section.
9. Separator according to one of the preceding claims, characterized in that the sealing is achieved radially inwardly by direct contact between the separator disks.
10. Separator according to claim 9, characterized in that for sealing radially inwardly, vertically adjacent separator disks (3b) lie directly against one another in a conical steep region (32) in which the angle of conicity β is smaller than the angle of conicity a in a conical separator disk section (31) outside the conical steep region (32).
11. Separator according to one of the preceding claims, characterized in that the separator disks (3b) in the upper separator disk assembly section (7) designed as a clarifying device have a greater vertical distance than the separator disks (3a) in the lower separator disk assembly section (6) designed as a separating device.
12. Separator according to one of the preceding claims, characterized in that the separator disk assembly (2) is divided into the lower separator disk assembly section (6) and the upper separator disk assembly section (7) by a separator disk (3b) having a larger diameter than the remaining separator disks (3a, 3c).
13. Separator according to one of the preceding claims, characterized in that a discharge of the one, lighter liquid phase (L1) occurs radially inwardly in the lower separator disk assembly section (6), and in that the other, heavier liquid phase (L2) is conducted into a rising channel (14) which passes axially through the entire disk packet.
14. Separator according to one of the preceding claims, characterized by discontinuously closable solids discharge openings (18).

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