EP1661626A1 - Disc separator - Google Patents

Abstract

A disc separator for removing impurities from a fluid, in which the fluid flows inwards from the dirt-collecting space in the stator between the discs on the rotor to a central channel and then to the outlet, the dirt-collecting space being divided axially by choke points into at least two sub-spaces from which the fluid flows in parallel streams as above. A disc separator for removing impurities from a fluid, comprising a rotor (2) with several axially-stacked discs (5) and a stator (3) with a dirt-collecting space (6) enclosing the rotor. The fluid path (7) proceeds from an inlet (8) to the collecting space (6), radially inwards between the discs (5) to a central run-off channel (9) and then out through an outlet (10); the collecting space (6) is divided axially by means of at least one choke point (11) into at least two sub-spaces (6a, 6b, 6c) from which the fluid flows in parallel streams between the discs (5) to the run-off channel (9). An independent claim is also included for a lubricant circuit for an internal combustion engine, especially in a motor vehicle, in which a single separator (1) as above is used both for main stream cleaning and side stream cleaning.

Description

The present invention relates to a plate separator for removing contaminants from a fluid.

A Tellerseparator comprises a rotor which rotatably carries a plurality of axially stacked and axially spaced apart plates, and a stator containing a dirt collecting space in which the rotor is arranged. In the plate separator, a fluid path is formed, which leads from an inlet into the protective collecting space, from the dirt collecting chamber radially inwardly between the plate into a central outflow channel and from the outflow channel through an outlet from the plate separator. During operation of the plate separator, it is flowed through said fluid path by a fluid to be cleaned, at the same time the rotor is rotating. By friction and inertia effects entrained by the fluid are thereby displaced radially outward and remain so in the dirt collecting space, while the fluid can flow inwards. Such plate separators work effectively and can remove relatively small contaminants from a relatively large volume flow. A particularly advantageous application for such Tellerseparatoren is seen in a lubricating oil circuit of an internal combustion engine, preferably in a motor vehicle, in order to clean the lubricating oil there from contaminants.

In a conventional lubricating oil circuit, it is common to carry out a main stream cleaning and independently of a side stream cleaning. The main stream cleaning serves to liberate the majority of the volume flow delivered in the lubricating oil circuit from relatively coarse impurities, which is usually realized by means of a filter whose porous filter body is flowed through by the main flow of the lubricating oil. In contrast, by-pass cleaning serves to remove relatively small impurities from a relatively small fractional flow (e.g., about 10% of the total volumetric flow), which can be realized, for example, by means of an inertial separator. Such an inertial separator can be, for example, a free-jet centrifuge or a plate separator of the type mentioned in the introduction. The effort to realize both a main stream cleaning and a Nebenstromreinigung in the lubricating oil circuit of an internal combustion engine is thus comparatively large.

The present invention addresses the problem of providing a Tellerseparator of the type mentioned an improved embodiment, which in particular simplifies the use in a lubricating oil circuit.

This problem is solved by the subject matter of the independent claim. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea of subdividing the dirt collecting space into at least two subspaces which communicate in a throttled manner and from which the fluid flows in parallel between the plates through to the outflow channel. By a throttle point between two consecutive subspaces prevails in the downstream subspace a reduced pressure. The invention uses the knowledge that the cleaning effect of such a Tellerseparators depends on the pressure gradient along the plate. With a smaller differential pressure, a significantly improved cleaning effect can be achieved. When Tellerseparator invention different input pressures are thus realized in the two subspaces of the dirt collecting space at the plates, which lead at a same output pressure in the outflow to different pressure differences along the plate. Within the Tellerseparators thus at least two zones are formed with different cleaning effect. In the zone or in that subspace in which there is a reduced pressure or a lower volume flow, there is an improved cleaning effect, so that even smaller particles can be retained in this area. With the help of the construction according to the invention thus the cleaning effect of the Tellerseparators can be improved overall.

Particularly advantageous is now a use of such a Tellerseparators in a lubricating oil circuit. Because with the help of this Tellerseparators both a main stream cleaning and a side stream cleaning can be realized simultaneously. Because the unthrottled subspace can be dimensioned so that it is sufficient for relatively coarse cleaning of the main stream, while the at least one throttled subspace can be easily dimensioned so that a relatively fine cleaning of the secondary stream can be realized. Thus, mainstream cleaning and by-pass cleaning take place simultaneously in one and the same disk separator. This leads to an extreme simplification in the structure of the lubricating oil circuit. Furthermore, it is further possible by the creation of additional, even more restricted subspaces, to further improve the filter effect with respect to even smaller partial flows.

Of particular advantage is also an embodiment in which the stator has a base and a removable removable element, the base containing the inlet and wherein the interchangeable element contains the dirt collecting space and is exchangeably connected to the base. Such an embodiment, which in principle can be implemented without the above-mentioned subdivision of the dirt collecting space into individual subspaces, the interchangeable element for maintenance or repair can be exchanged particularly easily. For example, after a predetermined operating time of the plate separator, the dirt collecting space substantially completely filled with contaminated contaminants. These contaminants can then be removed along with the interchangeable element and disposed of appropriately. The plate separator can be provided in the meantime with a new or with a cleaned removable element and is thus immediately ready for use again.

Preferably, in such an embodiment, the outlet is also formed in the base. As a result, inlet and outlet are formed on the same side of the stator, namely in the base, which greatly simplifies the design of the change element as an exchangeable spare part.

Also particularly advantageous is a development in which the base contains an idle channel which is closed when the change element by the exchange element and is opened when removing the change element and allows a flow of fluid through the idle channel before the exchange element is completely removed from the base , In particular, in the case of a liquid fluid, for example lubricating oil, this development helps to avoid contamination of the environment with the liquid or with the lubricating oil since the entire volume of liquid contained in the plate separator is completely removed from the inside of the idle channel before complete removal of the change element Can drain separator.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to identical or functionally identical or similar components.

Fig. 1

einen stark vereinfachten, prinzipiellen Längsschnitt durch einen Tellerseparator,

Fig. 2

eine vergrößerte Ansicht auf ein Detail II in Fig. 1, jedoch bei einer anderen Ausführungsform,

Fig. 3

eine Ansicht wie in Fig. 2, jedoch bei einer weiteren Ausführungsform,

Fig. 4

eine Ansicht wie in Fig. 1, jedoch bei einer anderen Ausführungsform.

Show, in each case schematically,

Fig. 1

a greatly simplified, fundamental longitudinal section through a Tellerseparator,

Fig. 2

2 is an enlarged view of a detail II in Fig. 1, but in another embodiment,

Fig. 3

a view as in Fig. 2, but in a further embodiment,

Fig. 4

a view as in Fig. 1, but in another embodiment.

According to FIG. 1, a plate separator 1 has a rotor 2 and a stator 3. The rotor 2 is rotatably mounted in the stator 3 about a rotation axis 4. The plate separator 1 typically contains a plurality of plates 5, which are stacked axially relative to one another with respect to the axis of rotation 4 and are axially spaced from one another and are also connected in a rotationally fixed manner to the rotor 2. Furthermore, the plate 5 are profiled in the special embodiment shown here in a longitudinal section frustoconical.

The stator 3 includes a dirt collecting space 6, in which the rotor 2 is arranged. Through the plate separator 1, a fluid path 7 passes, which is represented by individual arrows. This fluid path 7 leads from an inlet 8 into the dirt collecting space 6 and from the dirt collecting space 6 radially inwardly between the plates 5 into a central outflow channel 9. From the outflow channel 9, the fluid path 7 leads out of the plate separator 1 through an outlet 10.

In operation, the rotor 2 rotates at a predetermined speed and the fluid to be cleaned is guided along the fluid path 7 through the plate separator 1. The fluid, which may in principle be a gas or a liquid, in particular lubricating oil, carries impurities which have a greater density than the fluid. By frictional and inertial effects, these impurities can the fluid path 7 radially inwardly between the plates 5 therethrough do not follow, but remain in the dirt collecting space 6. Accordingly, purified fluid flows into the outflow channel 9 and out through the outlet 10 from the plate separator 1 addition.

The disk separator 1 according to the invention is characterized in that its dirt collecting space 6 is divided axially into at least two subspaces. In the exemplary embodiments illustrated here, the dirt collecting space 6 is subdivided by way of example into three subspaces 6a, 6b and 6c. The subdivision of the dirt collecting chamber 6 into the individual subspaces 6a, 6b, 6c takes place with the aid of at least one throttle point 11. In the present embodiment, two such throttling points 11 are provided in order to subdivide the dirt collecting space 6 into three subspaces 6a, 6b, 6c. It is noteworthy that the individual subspaces 6a, 6b, 6c are arranged one behind the other within the fluid path 7 and in each case communicate via one of the throttle points 11 with the directly upstream subspace 6a, 6b. At the same time, the fluid flowing into the subspaces 6a, 6b, 6c can flow from the subspaces 6a, 6b, 6c parallel between the plates 5 radially from the outside inwards to the outflow channel 9. Due to the throttle points 11 prevails in the downstream subspaces 6b, 6c each have a reduced pressure compared to the upstream subspaces 6a, 6b. This has the consequence that prevail in the respective subspaces 6a, 6b, 6c different pressure differences between the dirt collecting space 6 and the outflow channel 9. The invention uses the knowledge that the achievable with the Tellerseparator 1 cleaning effect of the prevailing between the dirt collecting space 6 and 9 outflow pressure difference. The smaller the pressure difference, the better the cleaning effect and the smaller the particles can be separated.

The plate separator 1 according to the invention thus achieves a particularly high cleaning effect due to the chosen construction. Furthermore, the disk separator 1 can be used particularly favorably in a lubricating oil circuit of an internal combustion engine, in particular in a motor vehicle, for cleaning the lubricating oil. It can be realized with the help of the plate separator 1, both the function of a main stream cleaning and the function of a side stream cleaning. The main stream cleaning, in which a comparatively large part of the total volume flow, which circulates in the lubricating oil circuit and thus flows through the disk separator 1, is cleaned of relatively coarse impurities. In the case of the plate separator 1, this is realized, for example, in the branch of the fluid path 7 leading through the unthrottled first subspace 6a, in which the greatest pressure difference between the dirt collecting space 6 and the discharge channel 9 prevails. By choosing the prevailing pressure difference and by positioning the first throttle point 11, which separates the unthrottled subspace 6a from the throttled second subspace 6b, the main volume flow flowing through this unthrottled first subspace 6a to the outflow channel 9 can be defined. The function of a Nebenstromreinigung can with the Tellerseparator 1 invention Help the throttled subspaces 6a, 6b are realized. Since there are smaller pressure differences between the dirt collecting chamber 6 and the outflow channel 9, although there are smaller volume flows, but for an improved cleaning effect.

In the specific embodiment shown here, two throttled subspaces 6b, 6c are provided, whereby the relatively small side stream can be additionally subdivided, which allows a further improvement of the cleaning effect.

The use of such a disk separator 1 in a lubricating oil circuit has the advantage that only a single component, namely the disk separator 1, is required to realize both the main stream cleaning and the by-pass cleaning. The structural complexity for the realization of the lubricating oil cleaning is reduced.

The throttle points 11 are realized in the embodiments shown here in each case with the aid of an annular gap 12 which extends in a parting plane 13, which in turn extends perpendicular to the axis of rotation 4. In the embodiment shown in Fig. 1, the annular gaps 12 are each formed by the fact that on the stator 3, an outer web 14 is attached or formed, which extends annularly in the parting plane 13. The outer web 14 limits the respective annular gap 12 radially outward. Furthermore, an inner web 15 is provided for each annular gap 12, which is likewise extends annularly in the respective parting plane 13, but is fastened or formed on the rotor 2 or on a plate 5 of the rotor 2. In this case, the respective inner web 15 limits the associated annular gap 12 radially inward.

Fig. 2 shows an alternative construction for the realization of the respective throttle point 11 and the respective annular gap 12. In this embodiment, an outer web 14 is again provided, which extends annularly in the parting plane 13 and is also attached or formed on the stator 3. The annular gap 12 is bounded by the outer web 14 radially outward. Radially inside the annular gap 12 is limited here by an outer edge 16 of the plate 5. This outer edge 16 is also again approximately in the parting plane 13th

In this embodiment, an inner web 15 is again provided which extends annularly in the parting plane 13 and thereby on the rotor 2 and on one of the plates 5 is attached or formed. The annular gap 12 is thereby bounded radially inwardly by the inner web 15. Radially outside the annular gap 12 is limited in this embodiment by an inner wall 17 of the dirt collecting space 6 and the stator 3.

While in the embodiment shown in Fig. 1 inlet 8 and outlet 10 on opposite sides of the stator. 3 Fig. 4 shows another embodiment in which inlet 8 and outlet 10 are arranged on the same side of the stator 3. In the embodiment of FIG. 4, the stator 3 has a base 18 and a removable element 19 which is removable from the base 18. The base 18 includes the inlet 8 and here also the outlet 10. Furthermore, the base 18 in the specific embodiment shown here includes an idle channel 20. The interchangeable element 19 contains the dirt collecting space 6 and is interchangeably connected to the base 18. Preferably, the change element 19 is connected via a not-shown screw thread with the base 18. The change element 19 can thus be placed parallel to the axis of rotation 4 on the base 18 and removed from it.

The rotor 2 comprises a rotor shaft 21 which rotatably supports the plates 5. The rotor shaft 21 is mounted at one end to the base 18 and at the other end to the interchangeable elements 19. For this purpose, the change element 19 includes a bearing 22 which is removable from the base 18 together with the change element 19. In the base 18 also a drive device not shown here is housed, which rotatably drives the rotor 2 during operation of the disk separator 1.

In the present example, the rotor shaft 21 is formed as a hollow shaft, which also has at least one radial opening 23. In this way, the rotor shaft 21 forms a part of the outflow channel 9, namely that component which leads to the outlet 10.

The arranged in the base 18 idle channel 20 leads, for example, to a relatively pressureless reservoir of the fluid circuit, the fluid to be cleaned by means of the plate separator 1. For example, this is a lubricating oil circuit of an internal combustion engine. The idle passage 20 then preferably leads into an oil sump of the internal combustion engine. In the base 18, the idle passage 20 terminates at a mouth opening 24 which is closed by the change element 19 when mounted on the base 18 replacement element 19.

During operation of the plate separator 1, the deposited impurities accumulate in the dirt collecting space 6. In the process, a cake which grows inwardly from the inner wall 17 forms solid or at least tough cake. The absorption capacity of the dirt collecting space 6 is limited, so that the dirt collecting space 6 must be emptied in predetermined maintenance intervals. When Tellerseparator 1 according to the invention, this can be particularly easily realized by removing the switching element 19. With the change element 19 while the dirt collecting space 6 is removed, including the contaminants deposited therein. The change element 19 can then be cleaned or simply replaced by a new one. In any case, it is particularly easy to dispose of the separated contaminants in this way.

When removing the change element 19, this is removed from the base 18 parallel to the axis of rotation 4. In this case, the interchangeable element 19 releases the mouth opening 24 of the idling channel 20, whereby the interior of the interchangeable element 19, which is filled with fluid during operation of the plate separator 1, can idle through the idling channel 20. In this way, pollution of the environment with the respective fluid, in particular with lubricating oil, can be avoided. The positioning of the mouth opening 24 and the connection of the switching element 19 to the base 18 are suitably matched to one another such that with a proper removal of the switching element 19, the fluid therein can flow completely through the idle channel 20 before the removable element 19 completely removed from the base 18 can be.

Claims (13)

Plate separator for removing impurities from a fluid, - With a rotor (2) rotatably carrying a plurality of axially stacked and axially spaced plates (5), - With a stator (3) containing a dirt collecting space (6), in which the rotor (2) is arranged, - A fluid path (7) from an inlet (8) in the dirt collecting space (6), from the dirt collecting space (6) radially inwardly between the plates (5) through into a central outflow channel (9) and from the outflow channel (9) by a Outlet (10) out of the Tellerseparator (1) leads out, - The dirt collecting space (6) by means of at least one throttle point (11) is axially divided into at least two subspaces (6a, 6b, 6c), of which the fluid can flow parallel between the plates (5) through to the outflow channel (9). Disc separator according to claim 1,
characterized,
in that such a throttle point (11) is formed by an annular gap (12) which lies in a parting plane (13) extending perpendicular to the axis of rotation (4). Disc separator according to claim 2,
characterized, that the annular gap (12) is bounded radially on the outside by an outer web (14) which extends annularly in the parting plane (13) and is fastened or formed on the stator (3), - That the annular gap (12) is bounded radially inwardly by an inner web (15) which extends annularly in the parting plane (13) and is fixed or formed on the rotor (2) or on a plate (5). Disc separator according to claim 2,
characterized, that the annular gap (12) is bounded radially on the outside by an outer web (14) which extends annularly in the parting plane (13) and is fastened or formed on the stator (3), - That the annular gap (12) is bounded radially inwardly by an outer edge (16) of a plate (5). Disc separator according to claim 2,
characterized, - That the annular gap (12) is bounded radially inwardly by an inner web (15) which is annular in the parting plane (13) extends and is fastened or formed on the rotor (2) or on a plate (5), - That the annular gap (12) is bounded radially outwardly by an inner wall (17) of the dirt collecting space (6). Disc separator according to one of claims 1 to 5,
characterized, - that the stator (3) has a base (18) and a removable removable element (19), - That the base (18) contains the inlet (8), - That the interchangeable element (19) contains the dirt collecting space (6) and is exchangeably connected to the base (18). Disc separator according to claim 6,
characterized,
that the outlet (10) is formed in the base (18). Disc separator according to claim 6 or 7,
characterized,
in that the rotor (2) has a rotor shaft (21) which is non-rotatably connected to the plates (5) and which is mounted at one end to the base (18) and at the other end to the interchangeable element (19). Disc separator according to claim 8,
characterized,
that the rotor shaft (21) is designed as a hollow shaft and forms a leading to the outlet (10) part of the outflow channel (9). Disc separator according to one of claims 6 to 9,
characterized,
in that the base (18) contains an idling channel (20) which is closed by the interchangeable element (19) when the interchangeable element (19) is mounted and is opened when the interchangeable element (19) is removed and allows the fluid to drain through the idling channel (20) before the change element (19) is completely removed from the base (18) Disc separator according to one of claims 1 to 10,
characterized,
is used that the plate separator (1) in a lubricating oil circuit of an internal combustion engine, in particular of a motor vehicle for cleaning of the lubricating oil. Disc separator according to claim 11,
characterized,
that the plate separator (1) works in the lubricating oil circuit at the same time as a main stream cleaning and as a side stream cleaning. Lubricating oil circuit of an internal combustion engine, in particular in a motor vehicle, in which a single disc separator (1) according to one of claims 1 to 12 is used both for mainstream cleaning and for secondary stream cleaning.

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