CA2406284C - A method of cleaning crankcase gas - Google Patents

Abstract

In connection with cleaning of crankcase gas from particles suspended therein and being heavier than the gas, the gas is caused to rotate in a chamber delimited in a stationary housing, so that the particles by centrifugal force are separated from the gas and are thrown towards a stationary housing. The rotation of the gas is accomplished by means of a rotor, which includes a stack of conical separation discs arranged coaxially with each other and concentrically with the rotational axis of the rotor. The gas to be cleaned is caused to flow through interspaces between the separation discs, while they are rotating, the particles by the centrifugal force being brought into contact with the insides of the separation discs.

Description

A METHOD OF CLEANING CRANKCASE GAS

This application is a divisional application of co-pending Canadian Patent Application No. 2,390,944, filed May 9, 2002.

The present invention relates to a method of cleaning crankcase gas, by means of centrifugal force, from solid or liquid particles suspended in the gas and having a larger density than the gas. Crankcase gas is a gas generated in a combustion engine, and containing particles in the form of oil and/or soot.

More closely the invention concerns cleaning of crankcase gas in a way such that the gas is conducted through a chamber, which is delimited by a stationary housing, and is caused to rotate in the chamber by means of a rotor kept in rotation around a rotational axis, the particles by upcoming centrifugal force being separated from the gas and thrown towards the stationary housing.
An apparatus for cleaning of crankcase gas in this way is known for instance through each one of the patents DE 35 41 204 Al and DE 43 11906 AI.

Thus, DE 35 41 204 Al shows an apparatus of this kind, in which the rotor is formed as a turbine or pump wheel, which is adapted to be brought into rotation by gas to be cleaned entering from below into said chamber. The gas to be cleaned is caused to flow through the turbine or pump wheel from its centre to its periphery, where it leaves the turbine or pump wheel, rotating at the same speed as this wheel. Particles are separated from the gas rotating in the chamber by centrifugal force, and cleaned gas leaves the chamber through an outlet at the upper part thereof. Particles separated from the gas deposit onto the surrounding wall of the chamber, liquid particles coalescing on the surrounding wall and liquid, thereafter, running down it and further out through an outlet situated at the bottom of the chamber.

DE 43 11 906 Al shows a similar apparatus for cleaning of crankcase gas, in which the rotor is adapted to be driven by means of pressurized lubricating oil coming from the combustion engine, the crankcase gas of which is to be cleaned in the apparatus. The driving lubricating oil is supplied to the rotor at its centre and leaves the rotor through tangentially directed outlets situated at a distance from the rotational axis of the rotor. The rotor constitutes in itself, in this case, a device for cleaning of the driving lubricating oil. The cleaned lubricating oil is released in the lower part of the chamber, through which the crankcase gas shall pass in order to be cleaned, and is returned therefrom to the lubricating oil system of the combustion engine. The crankcase gas is caused to pass axially through a narrow space delimited in the chamber between the rotor and the surrounding stationary housing. Gas rotating in the space is freed from particles suspended therein, which particles deposit onto the inside of the stationary housing, where liquid particles coalesce and liquid thus formed, thereafter, flows towards an outlet.
The two above described known apparatuses for cleaning of crankcase gas have rather a poor efficiency when it comes to separation of particles from a through flowing gas.

The object of the present invention primarily is to accomplish a method of cleaning crankcase gas, which is substantially more effective than the above described gas cleaning methods. It is suggested that a technique previously proposed for separating dust particles from air is utilised and improved.

Thus, the invention provides a method of cleaning crankcase gas, characterized in that - a rotor is kept rotating around a rotational axis in a chamber delimited by a stationary surrounding wall, which rotor comprises a stack of conical separation discs arranged coaxially with each other and concentrically with said rotational axis, the separation discs being provided with radially outer surrounding edges, - the crankcase gas to be cleaned is conducted through interspaces formed between the separation discs from gas inlets to gas outlets situated at differently large distances from the rotational axis of the rotor, so that the crankcase gas is caused to rotate with the rotor and the particles, as a consequence of upcoming centrifugal force, are brought into contact with the insides of the separation discs, and - separated particles by the rotation of the rotor are caused first to move a distance in contact with the separation discs substantially along the generatrices thereof towards said surrounding edge and then are thrown from the separation discs towards said surrounding wall.

US-A-2,104,683 and US-A-3,234,716 describe apparatus for cleaning of dust-laden air, operating according to similar principles. In each one of these patent specifications it is described how particles are separated from air flowing inwardly, towards the axis, between the conical separation discs and, having been brought into contact with the insides of the separation discs, are moved by means of centrifugal force towards the surrounding edges of the separation discs.
US-A-2,104,683 describes (with reference to figure 2) that particles in the areas of the radially outermost parts of the separation discs are influenced substantially only by centrifugal forces and move substantially along the generatrices of the separation discs, i.e. in straight paths along radii drawn from the rotational axis of the rotor, whereas particles in the areas of the radially inner parts of the separation discs also and to a very large degree are influenced by flowing gas and, thereby, move in a direction forming an angle with these generatrices. The flowing gas may move substantially freely between the separation discs and may adopt a flow direction determined by among other things the speed by which the gas enters the interspaces between the separation discs and the degree of influence from the rotating separation discs.
US-A-3,234,716 describes (with reference to the figures 3 and 4) how particles are separated in the interspaces between conical separation discs. After having got into contact with the insides of the separation discs the separated particles move substantially radially outwardly from the rotational axis of the rotor towards the surrounding edges of the separation discs.

For improvement of the separation efficiency in a preferred method according to the invention - separated particles moving in contact with the separation discs substantially along the generatrices thereof are caught and conducted, together with other particles caught in a similar way, further towards the said surrounding edges of the separation discs along paths forming an angle with said generatrices and - separated particles are caused to leave said paths and are thrown from the separation discs substantially only in limited areas spaced from each other along the surrounding edges of the respective separation discs.
The improvement hereby obtainable is that particles which have once been separated from the gas have increased possibilities in comparison with use of the previously known technology to remain separated from the gas and, thus, not to be entrained again by gas flowing at a large velocity through the space through which the particles have to pass on their way from the rotor to the surrounding stationary surrounding wall. Thus, the particles are collected by means of guiding or conducting members, after which they are conducted further on by means of the centrifugal force towards the surrounding edges of the separation discs while being agglomerated or coalesced to larger particles.

In an agglomerated form or as relatively large drops the separated particles are then thrown towards the stationary surrounding wall in limited areas distributed along the surrounding edges of the separation discs, whereas between such areas spaces are left for gas flow into or out of the interspaces between the separation discs.

The crankcase gas to be cleaned may be brought to flow between the separation discs either in a direction from or in a direction towards the rotational axis of the rotor. It is preferred that the flow is taking place in the direction from the rotational axis, as the flow will then be assisted by a pumping effect of the rotor on the gas. Thereby, no auxiliary means are needed to get the gas to flow through the interspaces between the rotating separation discs. The gas to be cleaned preferably is conducted into the interspaces through an inlet space delimited centrally in the stack of separation discs, whereas cleaned gas is conducted out of the interspaces to an outlet space in said chamber, which surrounds the stack of separation discs.

The separation discs may have the form of either complete or frustums of cones, each separation disc having either one large or several small holes in its central portion for through flow of gas to be cleaned or gas having been cleaned. Such holes in the separation discs form together with the interspaces between the separation discs central parts of one or more inlet or outlet spaces centrally in the stack of separation discs. For reasons having been given before it is preferred that the flow space centrally in the stack of separation discs communicates with the inlet and that the flow space surrounding the separation discs communicates with the gas outlet, so that gas to be cleaned is caused to flow in a direction from the rotational axis of the rotor through the interspaces between the separation discs.

In a cleaning operation according to the invention by means of separation discs, which are provided with guiding or conducting members of the aforementioned kind, liquid particles depositing on the surfaces of the separation discs will coalesce to larger drops, which when they reach said conducting members and move along these will coalesce to even larger drops. The liquid drops leaving the separation discs are, therefore, substantially larger than the liquid particles contained in the not yet cleaned gas. Even solid particles depositing on the surfaces of the separation discs will accumulate or be agglomerated to substantially larger units, before they are thrown away from the surrounding edges of the separation discs.
Since particles having got into contact with a separation disc will then move substantially along the generatrices thereof, it is suitable that said conducting members are distributed around the rotational axis of the rotor and have an extension such that two adjacent conducting members cross one and the same generatrix of the separation disc at points situated at different distances from the rotational axis of the rotor. Hereby, it can be assured that substantially all particles having got into contact with the separation disc are caught by the conducting members and may agglomerate or coalesce with other particles to larger units on or at these conducting members on their way towards the surrounding edge of the separation disc.

The conducting members advantageously are formed such that they can also serve as spacing members between adjacent separation discs. Then, each conducting member along the whole or parts of its extension may bridge the whole distance between two adjacent separation discs. More or less the conducting members will then also determine the flow direction of the gas flowing between the separation discs. Nothing prevents, however, that all or some of the conducting members extend only across part of the axial distance between adjacent separation discs. Preferably, a conducting member is firmly connected with a separation disc.

The stationary housing surrounding the rotor preferably has an outlet at the lower part of the chamber for liquid or sludge having been separated from the contaminated gas and having deposited on the surrounding wall of the chamber.
In an apparatus operable according to the invention the rotor may be driven by means of any suitable kind of driving device, e.g. an electrically, hydraulically or pneumatically driven motor.

The invention is further described in the following with reference to the accompanying drawing, which in figure 1 shows a longitudinal section through an apparatus formed for performing the method according to the invention and in figure 2 shows a section along the line II-II in figure 1.

In the drawing, figure 1 shows a sectional view of an apparatus formed for cleaning of crankcase gas from particles suspended therein and having a larger density than the gas. The apparatus includes a stationary housing 1 delimiting a chamber 2. The housing forms a gas inlet 3 to the chamber 2 for gas to be cleaned and a gas outlet 4 from the chamber 2 for cleaned gas. The housing further forms a particle outlet 5 from the chamber 2 for particles having been separated from the gas.
The housing 1 includes two parts, which are kept together by means of a number of screws 6. These screws 6 also are adapted to keep the housing fastened to suspension members 7 of an elastic material of some kind, through which the housing may be supported on a support (not shown).
Within the chamber 2 there is arranged a rotor 8 rotatable around a vertical rotational axis R. A motor 9, e.g. an electric motor, is arranged for rotation of the rotor 8. The rotor 8 includes a vertically extending central spindle 10, which at its upper end is journalled in the housing 1 through a bearing 11 and a bearing holder 12 and at its lower end is journalled in the housing I through a bearing 13 and a bearing holder 14. The bearing holder 14 is situated in the gas inlet 3 of the housing and, therefore, is provided with through holes 15 for incoming gas to be cleaned in the chamber 2.

The rotor 8 further includes an upper end wall 16 and a lower end wall 17, which two end walls are connected with the central spindle 10. The lower end wall 17 in a central portion is provided with through holes 18, so that the interior of the rotor may communicate with the gas inlet 3. Furthermore, the lower end wall 17 is provided with an annular flange 19, which is adapted to co-operate with a similar annular flange 20 of the bearing holder 14, so that gas entering through the gas inlet 3 is conducted into the interior of the rotor 8 through the aforementioned holes 18. The flanges 19 and 20 may be adapted to completely seal against each other, but a complete sealing between them is not necessary.
The reason for this shall be explained later.
The lower end wall 17 is formed in one piece with a hollow column 21 extending axially upwardly from the end wall 17 and sealingly surrounding the central spindle 10. The column extends all the way up to the upper end wall 16. In the area of the column 21 the central spindle 10 is cylindrical, preferably for cost reasons circular cylindrical, and the inside of the column 21 is formed in the same way as the outside of the spindle. The outside of the column 21 has a non-circular cross sectional form, as can be seen from figure 2.

A stack of conical separation discs 22 is arranged between the end walls 16 and 17. Each one of the separation discs has a frustoconical portion and in one piece therewith a plane portion 23 closest to the column 21. The plane portion, as can be seen in figure 2, is formed so that it may engage the non-circular column 21 such that the separation disc shall not be able to rotate relative to the column 21. Furthermore, the plane portion 23 is provided with several through holes 24. Irrespective of whether the holes in the various separation discs 22 are aligned axially with each other or not they form together with the interspaces between the central portions of the separation discs 22 a central inlet space 25 within the rotor 8 (see figure 1), which communicates with the gas inlet 3.
For the sake of clarity the drawing shows only a few separation discs 22 having large axial interspaces. In practice several more separation discs should be arranged between the end walls 16 and 17, so that relatively thin interspaces are formed between the discs.
Figure 2 shows the side of a separation disc 22 facing upwardly in figure 1.
In the following this side is called the inside of the separation disc, since it faces in a direction inwardly towards the rotational axis of the rotor. As can be seen the separation disc on its inside is provided with several elongated ribs 26 forming spacing members between the separation disc and the adjacent separation disc situated above it in the disc stack. Between the adjacent ribs 26 in an interspace between two separation discs flow passages 27 are formed for gas to be cleaned. The ribs 26 extend, as shown in figure 2, along curved paths and form at least at the radially outer surrounding portions of the separation discs an angle with the generatrices of the separation discs. As a consequence of the curved form of the ribs 26 also the flow passages 27 for gas to be cleaned extend along paths which are curved in a corresponding way. The ribs 26 extend preferably across substantially the whole of the conical portion of every separation disc and end up in the vicinity of the radially outer surrounding edge of the separation disc.

An annular space 28 surrounds the rotor 8 in the housing 1 and forms a part of the chamber 2.

The apparatus described above and shown in the drawing operates in the following manner when cleaning crankcase gas from particles suspended therein and having a larger density than the gas. It is assumed in this case that the particles are of two kinds, namely solids in the form of soot particles and liquid particles in the form of oil particles.

By means of the motor 9 the rotor 8 is kept in rotation. Gas contaminated by particles is introduced into the housing 1 from below through the inlet 3 and is conducted further on into the central inlet space 25. From here gas flows into and radially outwardly through the interspaces between the separation discs 22.
While the gas flows between the separation discs 22 it is brought into rotation as a consequence of the rotation of the rotor. Thereby, the particles suspended in the gas are forced by the centrifugal force to move towards and into contact with the insides of the separation discs, i.e. the sides of the separation discs facing upwardly in figure 1. Upon contact with the separation discs the particles will be entrained thereby and, thereafter, be influenced mainly by centrifugal forces causing the particles to move radially outwardly along the generatrices of the separation discs. The movement of the particles along these generatrices is illustrated by means of arrows in figure 2.
Owing to the ribs 26 forming an angle with the generatrices of the separation discs the ribs will catch particles moving in contact with the separation discs towards the surrounding edges thereof. The particles caught will be conducted further along the ribs 26 which, thus, will serve as guiding members for the particles.

As to separated liquid particles, these coalesce to larger particles while moving in contact with the separation discs 22. Further such coalescense occurs when the liquid particles move further on along the ribs 26 towards the surrounding edges of the separation discs. This latter movement also occurs by influence of centrifugal force. When the liquid particles reach the surrounding edges of the separation discs the coalescense has proceeded so far that the liquid is thrown out of the rotor in the form of relatively large liquid drops. These liquid drops hit the surrounding wall of the housing 1, after which the liquid thus formed runs downwardly along this surrounding wall and out through the particle outlet 5.
Said liquid drops will leave the separation discs in limited areas situated at a distance from each other along the surrounding edges of the respective separation discs, i.e. in the areas of the radially outer ends of the ribs 26.
As to separated solids, also these move in contact with the separation discs towards said ribs 26 and further in contact with these ribs towards the radially outermost edges of the separation discs. Together with the liquid drops the particles are thrown from the rotor against the surrounding wall of the housing 1, where they are entrained by down running liquid to and out through the particle outlet 5.

As can be seen from figure 2, the ribs 26 have a location and an extension such that two adjacent ribs on the same separation disc cross one and the same generatrix of the separation disc at different distances from the rotational axis of the rotor. In other words the ribs 26 distributed around the rotational axis partly overlap each other, if they are seen from the rotational axis. Such overlapping may be to a larger or smaller extent, so that substantially all particles being brought into contact with the underside of the separation disc can be caught by means of curved ribs of this kind and by the ribs be conducted further towards the surrounding edge of the separation disc.

The above described function of the curved ribs 26 is obtained independently of the chosen rotational direction for the rotor. The ribs need not necessarily be curved as shown in figure 2. The main thing is that they form an angle with the generatrices of the separation discs and that this angle is such that particles having been caught by the ribs may be guided along these ribs towards the surrounding edges of the separation discs. As to solid particles, the angle of repose of the particles has to be considered in each particular case.
The gas which in each interspace between adjacent separation discs has been freed from particles leaves the interspace through spaces situated between the aforementioned areas, at which separated particles are thrown away from the separation discs towards the stationary housing. The cleaned gas leaves the chamber 2 through the gas outlet 4. As a consequence of the rotor rotation the gas flowing through the interspaces between the separation discs 22 will get an increased pressure. Thus, a higher pressure prevails in the space 28 around the rotor 1 and in the area of the gas outlet 4 than in the central space 25 and in the gas inlet 3. This means that a possible leak between the flanges 19 and 20 does not have any substantial importance. Uncleaned gas, thus, may not flow between the flanges 19 and 20 directly from the gas inlet 3 to the gas outlet but, instead, some cleaned gas will flow back into the central space 25.
Thanks to the above described concentration or agglomeration of particles on the surfaces of the separation discs, particularly close to the spacing members 26, solid or liquid material having been separated from the gas wiil leave the separation discs in particle aggregates or drops so large that these will not to a substantial degree be entrained out of the housing 1 by the gas flowing through the space 28.
The described and shown apparatus has a large separation efficiency and may be produced very cheaply upon a suitable choice of material for the different parts of the apparatus. Thus, most of the apparatus parts may be made of plastics. Apart from screws and bearings only the central spindle 10 should preferably be made of metal.

As already mentioned the lower end wall 17 of the rotor and the column 21 may be made in one piece, suitably out of plastics. A part of the rotor formed in this way may form a basis for an automatized mounting of the separation discs 22, which also suitably are made of plastics. The whole rotor mounted in this way, with or without a spindle 10, may form an inexpensive unit for the finished apparatus, which is easily exchangeable.

Claims (9)

Claims

1. A method of cleaning crankcase gas, coming from a combustion engine, from solid or liquid particles suspended therein and having a larger density than the cranckcase gas, wherein:
a rotor is kept rotating around a rotational axis (R) in a chamber, that is delimited by a stationary surrounding wall, said rotor comprising a stack of conical separation discs arranged coaxially with each other and concentrically with said rotation axis and being provided with radially outer surrounding edges;
the crankcase gas to be cleaned is conducted through interspaces formed between the separation discs from gas inlets to gas outlets situated at different distances from the rotational axis (R) of the rotor, so that the crankcase gas is caused to rotate with the rotor and the particles, thereby, as a consequence of upcoming centrifugal force are brought into contact with the inside surfaces of the separation discs; and separated particles by the rotation of the rotor are first brought to move a distance in contact with the separation discs substantially along generatrices thereof towards said surrounding edges and after that are thrown from the separation discs directly out into said chamber delimited by said stationary surrounding wall.

2. A method according to claim 1, in which the crankcase gas to be cleaned is conducted between the separation discs in a direction from the rotational axis (R) towards said surrounding edges of the separation discs.

3. A method according to claim 2, in which the crankcase gas to be cleaned is conducted into a central inlet space in the stack of separation discs and from there through the interspaces between the separation discs, after which cleaned crankcase gas is conducted out of the chamber through a gas outlet communicating with an outlet space that is formed by and between the stack of separation discs and the stationary surrounding wall.

4. A method according to any one of claims 1 to 3, in which the crankcase gas to be cleaned is entrained in the rotor rotation, while passing through the interspaces between the separation discs, by means of members bridging the interspaces between adjacent separation discs.

5. A method according to any one of claims 1 to 4, wherein:
separated particles moving in contact with the separation discs substantially along the generatrices thereof are caught and conducted, together with other particles caught in a similar way, further towards said surrounding edges of the separation discs along paths forming an angle with said generatrices; and separated particles are caused to leave said paths and be thrown from the separation discs substantially only in limited areas situated at a distance from each other along the surrounding edges of the respective separation discs.

6. A method according to claim 5, in which the crankcase gas is conducted between the separation discs along flow paths substantially in parallel with said paths for the separated particles.

7. A method according to claim 1, in which the crankcase gas to be cleaned is conducted between the separation discs in a direction towards the rotational axis (R).

8. A crankcase gas cleaning apparatus for cleaning of crankcase gas from oil particles suspended therein and having a larger density than the gas, said apparatus having:
a stationary housing delimiting a chamber and a rotor rotatable in the chamber about a rotational axis (R) and arranged to bring gas to be cleaned in rotation, a gas inlet for said gas to be cleaned;
a gas outlet for cleaned gas;

an oil outlet for oil having been separated from the gas;
the rotor including a stack of conical separation discs arranged coaxially with each other and concentrically with the rotational axis (R) of the rotor, said conical separation discs having radially outer edges and delimiting between themselves interspaces for through flow of gas; and a space formed in the stack of separation discs, communicating with radially inner parts of said interspaces between the separation discs;
wherein a part of said chamber, extending around the rotor, is delimited by and between said stationary housing and the stack of separation discs, so that radially outer parts of said interspaces between the discs open directly into said part of the chamber;
said oil outlet is placed so that it receives oil having been thrown from said outer edges of the separation discs onto the surrounding stationary housing and running downwardly; and said part of the chamber communicates with one of said gas inlet and said gas outlet, and said space formed in the stack of separation discs communicates with the other one of said gas inlet and said gas outlet.

9. A crankcase gas cleaning apparatus according to claim 8, in which said space formed in the stack of separation discs communicates with said gas inlet and said part of said chamber communicates with said gas outlet.