Patent Description:
Coalesced liquid separators are commonly used to separate coalesced liquid, e.g. ammonia, water, and/or oil from an aerosol-containing gas stream such as a compressed or uncompressed airflow and/or a hydrogen gas stream. Oil separators are an example of coalesced liquid separators, commonly used to separate oil from airflows in air compressors and pumps such as vacuum pumps and cryo pumps. Oil separation can reduce contamination of the airflows and enable recycling of the separated oil, thereby improving reliability and cost efficiency of the pump/compressor.

Oil separators where oil is passed through one or a plurality of filter units are known. For example, a conventional oil separator is disclosed in <CIT> and is briefly described herein with reference to <FIG>.

The oil separator of <FIG> comprises an outer housing <NUM> having a housing flange <NUM> and a housing lid <NUM> provided as a cylindrical bell and removably mounted on the flange. The housing is rotationally symmetrical relative to a longitudinal axis <NUM>. An airflow enters through a centrally located inlet <NUM> formed in the flange and exits through a centrally located outlet <NUM> formed in the housing lid.

The oil separator has a multi-stage coalescing filter including two cylindrical filter elements (i.e. an inner <NUM> and an outer <NUM> element). The filter elements are detachably mounted onto the flange <NUM> by insertion into respective annular indentations <NUM>, <NUM>. A diameter of the inner filter element <NUM> is smaller than the diameter of the outer filter element <NUM>, such that the two elements are nested, thereby providing a gap for liquid (e.g. oil) drainage and gas transfer between the filter elements. Thus, multi-stage coalescing filtration can be achieved. In use, the oil-containing airflow enters the housing <NUM> through the inlet <NUM> and flows radially outward through the filter elements <NUM>, <NUM> before exiting the housing through the outlet <NUM>. As the airflow passes through the filter elements, the filter elements separate and retain oil from the airflow. Under the influence of gravity, the separated oil runs down outer sides of the filter elements and accumulates in respective annular grooves <NUM>, <NUM> formed in the flange. The grooves are in fluid communicated with respective oil passages <NUM>, <NUM> entering a common channel (not shown) through which the separated oil can be returned to a collection point, e.g. a compressor or a vacuum pump.

A problem arises when the gas stream can follow the same flow path as the separated coalesced liquid, thereby bypassing the filter elements (i.e. aerosol bypass). This can cause the coalesced liquid separator to function less reliably and/or efficiently.

Thus, it is desirable to provide a multi-stage coalescing filter which can reliably separate coalesced liquid from an aerosol-containing gas stream while simultaneously preventing the gas stream from bypassing the filter elements.

<CIT> relates to a draining and sealing device for mist eliminators.

<CIT> relates to an improvement in a mist eliminator element.

<CIT> relates to a combustion engine crankcase venting.

In a first aspect, the present invention provides a multi-stage coalescing filter for separating coalesced liquid from an aerosol-containing gas stream, the multi-stage coalescing filter including:.

Advantageously, the saturable porous element can reliably prevent aerosol bypass via the chamber, while simultaneously allowing the received coalesced liquid (e.g. oil) to flow to the outlet via capillary action in the porous element. Thus, it can be ensured that the coalesced liquid is reliably separated from the aerosol-containing gas stream and the separated coalesced liquid can be returned to a collection point such as a pump/compressor, e.g. via scavenge lines, thereby recycling it. Therefore, the present multi-stage coalescing filter can provide reliable coalesced liquid separation combined with improved efficiency.

A sump side of the or each inlet may be fitted with a pre-filter element for purifying the separated coalesced liquid before it enters the chamber. Conveniently, such a pre-filter element can aid the purification of the coalesced liquid separated from the gas stream by the filter elements prior to its return to a collection point, e.g. a compressor or a vacuum pump. For example, the pre-filter element may be mounted across an orifice of an orifice-containing part that is detachably attached to the sump side of a respective inlet of the chamber. In this way, the pre-filter element can be easily replaced or cleaned as needed.

The chamber may have plural inlets and/or outlets arranged in respective circumferential rows. Thus, the inlets and/or outlets can be correspondingly arranged around the respective tubular filter elements to receive the coalesced liquid from the or each sump.

The end cap may comprise a bottom portion which defines a floor of the chamber and the one or more outlets, and a top portion which defines a ceiling of the chamber and the one or more inlets, the top portion being removably couplable to the bottom portion to allow location of the porous element in the chamber. Advantageously, this arrangement facilitates end cap assembly and access to the porous element. For example, the porous element can be installed to the end cap or accessed, e.g. for maintenance purposes, by removing the top portion of the end cap to expose the chamber.

The floor and/or ceiling of the chamber may include one or more projections, such as ribs, extending into the chamber. Typically the projections are annular. When there are plural projections, they may be radially spaced. When the porous element is formed of a compressible material, e.g. a foam, the projections can create pinch points which compress the porous element at selected locations, thereby decreasing an amount of coalesced liquid required to saturate the porous element at these locations. Thus, these selected locations can quickly saturate when the coalesced liquid first comes into contact with the porous element to act as gas stoppers to reduce the risk of aerosol bypass during these initial stages of coalesced liquid drainage through the chamber.

The multi-stage coalescing filter may have just two nested tubular filter elements and a single annular sump.

Alternatively, however, the multi-stage coalescing filter may have three or more nested tubular filter elements and a plurality of annular sumps. Then, one option for the chamber is to be a single undivided space which receives coalesced liquid from all the sumps. The single chamber in this case has one or more inlets from each sump. Another option is for the chamber to be divided into separate (typically annular) sub-chambers which receive coalesced liquid from respective sumps. In the latter case, each sub-chamber has its own one or more inlets and outlets, and the porous element is also formed as separate sub-elements which are respectively housed in the sub-chambers.

The end cap may provide a respective pair of annular side walls for the or each sump, the side walls extending up opposing sides of the respective pair of successive tubular filter elements to isolate the coalesced liquid collected in the sump from the filter elements. Advantageously, this can ensure that coalesced liquid separated by the filter elements does not return to the filter elements to contaminate them and reduce filtration efficiency.

The annular side walls may have different heights. For example, when the filter is configured for an aerosol-containing gas stream that passes radially outwardly through the nested filter elements, the outer side wall of each sump can be higher than inner side wall. Advantageously, the separated coalesced liquid can thus accumulate in the respective sump but is primarily prevented from contacting and saturating the downstream filter element and thereby reducing its filtration efficiency. Conversely, when the filter is configured for an aerosol-containing gas stream that passes in the opposite direction radially inwardly through the nested filters, the inners side wall of each sump can be higher than the outer side wall to achieve the same effect. When a pre-filter element is fitted to the or each inlet, as described above, a height of the pre-filter element may be less than the height of the shorter annular side wall.

When the end cap comprises a bottom portion and a top portion, one of the annular side walls of a given sump may be formed by the top portion and the other of the annular side walls of the given sump may be formed by the bottom portion. Advantageously, this can enable the relative height difference between the two annular side walls to be changed simply by replacing the top portion of the end cap. However, alternatively, both of the annular side walls of at least one of the sumps may be formed by the top portion. Particularly when there are plural annular sumps, this can simplify the structure of the end cap.

The end cap of the first aspect may be a first end cap having a central port for communicating the aerosol-containing gas stream with the inside of the innermost tubular filter element, and the multi-stage coalescing filter may further have a second end cap at the opposite ends of the tubular filter elements to the first end cap to close off said opposite ends. When the filter is configured for an aerosol-containing gas stream that passes radially outwardly through the nested filter elements, the central port receives the aerosol-containing gas stream as an incoming gas stream, and when the filter is configured for an aerosol-containing gas stream that passes radially inwardly through the nested filter elements, the central port receives the aerosol-containing gas stream as an outgoing aerosol-containing gas stream. Either way, the first end cap and the second end cap ensure that the aerosol-containing gas stream passes as intended through the filter elements and the central port. The second end cap may be formed as a single component which closes off all the opposite ends, or as several sub-components which close off respective opposite ends.

Alternatively, the end cap of the first aspect may be a first end cap which closes off a central bore of the innermost tubular filter element to gas flow. In this case, the multi-stage coalescing filter may further have a second end cap at the opposite ends of the tubular filter elements to the first end cap to close off said opposite ends except for a central port formed in the second end cap for communicating the aerosol-containing gas stream with the inside of the innermost tubular filter element. Again, when the filter is configured for an aerosol-containing gas stream that passes radially outwardly through the nested filter elements, the central port receives the aerosol-containing gas stream as an incoming gas stream, and when the filter is configured for an aerosol-containing gas stream that passes radially inwardly through the nested filter elements, the central port receives the aerosol-containing gas stream as an outgoing aerosol-containing gas stream. In this alternative, however, separated coalesced liquid may accumulate in a central sump formed at the base of the central bore, the first end cap having a liquid-only escape route from the central sump. For example, the escape route can be an inlet to the chamber housing the porous element, or an inlet to a further chamber housing a further porous element and having an outlet therefrom. Either way, the escape route is configured to allow coalesced liquid to be guided out of the filter while simultaneously preventing the aerosol-containing gas stream from bypassing the nested filter elements. The sump side of the inlet may be fitted with a pre-filter element as discussed above.

The porous element may be formed of any material or any combination of materials which is saturable and can reliably allow the received coalesced liquid to flow through it via capillary action to the outlets while simultaneously preventing the aerosol-containing gas stream from bypassing the nested filter elements. Thus the material of the porous element can be selected to control its porosity and saturability as required. For example, the porous element may be formed of any one or any combination of: glass fibre medium, synthetic fibre matrix, non-woven material, foam, and sintered material, such as sintered plastic. If using glass fibre media to form the filter elements and the porous element, selection of a suitable grade for the porous element can be informed by the choice of glass fibre media for the filter elements. A foam porous element can advantageously be compressed to more completely fill the chamber, thereby further reducing a risk of aerosol bypass. Sintered material, e.g. sintered plastic, such as a commercially available product e.g. available from Porvair™, generally have well-defined pore sizes which allow reliable control of coalesced liquid flow rates through the porous element at a range of differential pressures.

The filter of the first aspect is typically intended to be used inside a pressure tight housing of a coalesced liquid separator. For example, such a housing may have a bowl which contains the filter and a head which seals to the bowl and provides an inlet arrangement and an outlet arrangement for the aerosol-containing gas stream. The bowl is removable from the head to allow access to and replacement of the filter. The bowl and the head are generally cast or machined metal components in order to provide adequate strength and pressure tightness. The filter is typically a consumable item. Moreover, the filter does not need to play a role in maintaining pressure tightness with the external environment. Accordingly, the end cap(s) can conveniently be formed of plastic material. For example, it may be formed by injection moulding, which allows complex end cap shapes (such as the end cap forming a reservoir of the second aspect) to be formed rapidly and cheaply.

In a second aspect, the present invention provides a coalesced liquid separator (e.g. an oil separator) including:.

The housing may have a bowl which contains the filter and a head which seals to the bowl and provides the inlet arrangement and the outlet arrangement. The housing (e.g. the bowl and/or the head) may be formed of metal, e.g. aluminium alloy, cast iron or steel, or may be formed of a polymer such as polycarbonate.

The separator may be configured so that, in use, between an upper position at the top surface of coalesced liquid collected in the sumps and a lower position at the outlets from the chamber, there is a pressure differential in addition to any hydraulic head in the coalesced liquid between the upper and lower positions, the pressure differential being such as to drive the coalesced liquid from the sump and through the chamber (i.e. by a higher pressure at the upper position than at the lower position). Usefully, the pressure differential can thus overcome any resistance to liquid flow through the porous element, due to e.g. surface tension effects. For example, the pressure differential may at least <NUM> kPa, and preferably may be at least <NUM> kPa. The outlets may guide the received coalesced out of the filter and into a collection tank of the liquid separator. To achieve the pressure differential, the collection tank should be isolated from the gas stream arriving in the separator through the inlet arrangement.

The present invention includes combination of any of the aspects and optional features described, except where such a combination is clearly impermissible or expressly avoided.

The present invention provides a multi-stage coalescing filter for separating coalesced liquid. In the examples discussed below, the coalesced liquid is oil and the aerosol-containing gas stream is an airflow, e.g. from a compressor or a pump such as a cryo pump or a vacuum pump. The multi-stage coalescing filter is installable in a housing of a coalesced liquid separator (e.g. an oil separator). When an airflow enters the separator through an inlet arrangement, it is directed to pass through the multi-stage coalescing filter, and then exits the separator through an outlet arrangement. For example, the housing may have a bowl which contains the filter and a head which seals to the bowl and provides the inlet arrangement and the outlet arrangement. The filter separates oil from the airflow, the separated oil accumulating in a collection tank of the housing. From there, the separated oil can be scavenged, recycled or disposed of as appropriate.

A multi-stage coalescing filter is described with reference to <FIG>, <FIG>, <FIG>, and <FIG>. Corresponding features in these and subsequent drawings are indicated by the same reference numbers.

<FIG> and <FIG>, and <FIG> show respective cross-sectional views of bottom portions of variants of a multi-stage coalescing filter <NUM>. All variants are axisymmetric. Further, in all variants, the multi-stage coalescing filter has a (first) bottom end cap <NUM> supporting coaxial, nested, tubular filter elements 105a, 105b, 105c in an upright configuration. A further (second) top end cap (not shown) at the opposite ends of the filter elements 105a, 105b, 105c closes off said opposite ends. The top end cap may be formed as a single component which closes off all the opposite ends, or as several sub-components which close off respective opposite ends.

In the examples of <FIG>, <FIG>, <FIG> and <FIG> there are two filter elements: an inner filter element 105a and an outer filter element 105b, while in the examples of <FIG> and <FIG>, there are three filter elements 105a, 105b, 105c.

Turning first to <FIG>, <FIG>, <FIG> and <FIG>, the filter elements 105a, 105b are spaced from each other such that the bottom end cap <NUM> between them forms an annular sump <NUM>. The bottom end cap has a central port <NUM> for receiving the airflow from the inlet arrangement of the separator and communicating the airflow with the inside of the inner filter element 105a. A corresponding port is not formed in the top end cap. In use, the airflow enters through the central port and passes radially outwardly through the nested filter elements, whereby the filter elements separate oil from the airflow. Under the action of gravity, separated oil from the airflow is collected in the sump <NUM>.

The direction of the airflow is indicated by the grey arrows, the reducing oil burden of the airflow as it passes through the filter elements 105a, 105b being indicated by the lighter shade of the arrows.

The bottom end cap <NUM> is formed of a bottom portion 102a and a top portion 102b. The top potion is removably couplable to the bottom portion such that the two portions form a chamber within the bottom end cap. In particular, the bottom portion defines a floor of the chamber and the top portion defines a ceiling of the chamber. The removably couplable top and bottom portions enable the location of a porous element <NUM> inside the chamber. <FIG> show respective plan views of the bottom portion of the bottom end cap of <FIG>, the porous element, and the top portion of the bottom end cap of <FIG>. The plan views are supplemented by respective schematic cross-sectional views matching those shown in <FIG>.

The chamber formed by the bottom 102a and top 102b portions of the bottom end cap <NUM> has inlets <NUM> in fluid communication with the sump <NUM> for receiving the oil from the sump, the inlets being defined by the top portion. The chamber further has outlets <NUM> for guiding the received oil out of the filter, the outlets being defined by the bottom portion. Both the inlets and the outlets are arranged in respective circumferential rows (shown respectively in <FIG>).

In <FIG> and <FIG>, the bottom portion 102a has a single row of circumferential inlets <NUM> and a single row of circumferential outlets <NUM>, while in <FIG> and <FIG>, the bottom portion 102a has a single row of circumferential inlets and two rows of circumferential outlets. The oil received into the chamber from the sump <NUM> comes into contact with the porous element <NUM>, thereby causing the porous element to saturate. This allows the received oil to flow through the porous element to the outlets via capillary action, while simultaneously preventing the airflow from passing through the chamber and thereby bypassing the outer filter element 105b. From the outlets, the separated oil can drop into the collection tank of the housing. The inlets, chamber containing the porous element and the outlets thus form an oil-only escape route from the filter.

In use, between an upper position at the top surface of coalesced liquid collected in the sump <NUM> and a lower position at the outlets <NUM> from the chamber, there is a pressure differential in addition to any hydraulic head in the coalesced oil between the upper and lower positions. This is because the pressure of the airflow passing through through the nested filter elements 105a, 105b is higher than the pressure of air in the collection tank. For example, the pressure may be at least <NUM> kPa higher, and preferably may be at least <NUM> kPa higher. This pressure differential overcomes any resistance to oil flow through the porous element <NUM> and drives the coalesced oil from the sump and through the chamber. To achieve the pressure differential, the collection tank should be isolated from the airflow arriving in the separator through the inlet arrangement. As indicated above, the saturation of the porous element <NUM> isolates the collection tank from the airflow passing through the filter elements.

The porous element can be formed of any material or any combination of materials which is saturable and can reliably allow the received oil to flow through it via capillary action to the outlet while simultaneously preventing the airflow from bypassing the nested filter elements via the chamber. The porous element can be generally formed of different materials to control its porosity and saturability as required. For example, the porous element may be formed of any one or any combination of: glass fibre medium, synthetic fibre matrix, non-woven material, foam, and sintered material such as sintered plastic. Evidently the pores of the porous element should be interconnected to enable the oil flow through the element. If using glass fibre media to form the filter elements and the porous element, selection of a suitable grade for the porous element can be informed by the choice of glass fibre media for the filter elements. A foam porous element can advantageously be compressed to more completely fill the chamber, thereby further reducing a risk of aerosol bypass. Sintered plastic, such as a commercially available product e.g. available from Porvair™, generally have well-defined pore sizes which allow reliable control of oil flow rates through the porous element at a range of differential pressures.

The bottom end cap <NUM> also provides a pair of annular side walls <NUM> for the sump <NUM>, the side walls extending up opposing sides of the inner 105a and outer 105b tubular filter elements to better isolate the oil collected in the sump from the filter elements. The side walls further have different heights. In this example, the outer side wall is higher than the inner side wall. Thus, as the airflow passes radially outwardly through the nested filter elements, the separated oil can accumulate in the sump but is primarily prevented from saturating the outer filter element (which removes finer oil droplets from the airflow than the inner filter element). If the filter was configured for an airflow that passes in the opposite direction, i.e. radially inwardly through the nested filters, then, the inner side wall of the sump would be higher than the outer side wall to achieve the same effect.

In the example of <FIG>, the inner wall <NUM> is formed by the bottom portion 102a of the bottom end cap <NUM>, while the outer wall <NUM> is formed by the top portion 102b. This enables the relative height difference between the two annular side walls to be changed simply by changing/replacing the top portion of the bottom end cap. In contrast, in the example of <FIG>, <FIG>, and <FIG>, both annular side walls are formed by the top portion of the end cap, thereby improving the structural simplicity of the bottom end cap.

The variants shown in <FIG> and <FIG> chiefly differ from those shown in <FIG> and <FIG> by including pre-filter elements <NUM> and orifice-containing parts <NUM> which are fitted to the sump sides of the chamber inlets <NUM>, as well as including radially spaced annular ribs <NUM> in the chamber <NUM>. In particular, each chamber inlet <NUM> is in fluid communication with its respective sump <NUM> via a pre-filter element <NUM> mounted on a respective orifice-containing part <NUM>, the orifice being detachably attached to the inlet. Thus, the separated oil from the first filter element can be at least partially purified by passing through the pre-filter element before being guided out of the multi-stage coalescing filter, e.g. for return to a compressor/ vacuum pump. In these examples, the orifice-containing parts <NUM> extend upwardly from the respective chamber inlets to a height that is less than that of the shorter annular side wall of the respective sump to allow the collected oil to drain from the sump into the chamber without contacting and saturating the respective pair of filter elements.

Turning to the radially spaced annular ribs <NUM> shown in <FIG> and <FIG>, when the porous element <NUM>, <NUM>' is formed of a compressible material, e.g. a foam, the ribs can advantageously compress the porous element at selected locations to create pinch points in the porous element at which the amount of oil required to saturate the porous element is reduced. Thus, the pinch points quickly saturate when the oil first comes into contact with the porous and act as gas stoppers to reduce the risk of aerosol bypass during these initial stages of oil drainage through the chamber.

Further modifications of the multi-stage coalescing filter <NUM> are possible. For example, the multi-stage coalescing filter can have three nested tubular filter elements <NUM>, 105b ,105c and two annular sumps <NUM>, <NUM>', as shown in <FIG> and <FIG>. In this case, one option for the chamber is to be a single undivided space which receives oil from all the sumps. Examples of this are shown in <FIG> and <FIG> where the single chamber has one or more inlets from each sump <NUM>, <NUM>'. Another option is for the chamber to be divided into separate (annular) sub-chambers which receive oil from respective sumps <NUM>, <NUM>'. This option is shown in <FIG> and <FIG>, where each sub-chamber has its own one or more inlets and outlets, and the porous element <NUM> is formed as separate sub-elements <NUM>, <NUM>' respectively housed in the sub-chambers.

In another modification (shown in <FIG> and <FIG>), the central port is formed in the top end cap rather than the bottom end cap. In this case, separated oil accumulates in a central sump <NUM>" formed at the base of the central bore of the innermost filter element 105a, the bottom end cap having a further oil-only escape route from the base of the central bore (i.e. an inlet <NUM>", a further, central chamber containing a porous element <NUM>", and an outlet <NUM>") configured to allow oil to drop into the collection tank without causing the airflow to bypass the filter elements. In the examples of <FIG> and <FIG>, the central sump <NUM>" has an annular side wall <NUM>" extending up the inner side of the innermost tubular filter element 105a. The central chamber is formed entirely by the bottom portion 102a of the bottom end cap.

Additionally, all variants of the multi-stage coalescing filter shown in <FIG>, and <FIG> include one or more radially spaced annular ribs <NUM> analogous to these shown in and discussed in relation to <FIG> and <FIG>.

Other drain mechanisms are also possible including conventional manual drain mechanisms, electronic auto-drain mechanisms, timed actuator-activated drain mechanisms, etc..

Advantageously, each of the multi-stage coalescing filters described above in relation to <FIG> provides an oil-only escape route from the filter, thereby improving filtration efficiency.

The features disclosed in the description, or in the following claims, or in the accompanying drawings, expressed in their specific forms or in terms of a means for performing the disclosed function, or a method or process for obtaining the disclosed results, as appropriate, may, separately, or in any combination of such features, be utilised for realising the invention in diverse forms thereof.

Claim 1:
A multi-stage coalescing filter (<NUM>) for separating coalesced liquid from an aerosol-containing gas stream, the multi-stage coalescing filter including:
an end cap (<NUM>) having a chamber formed within; and
a plurality of coaxial, nested, tubular filter elements (105a, 105b, 105c) supported upright on the end cap;
wherein:
pairs of successive filter elements are spaced from each other such that the end cap between pairs of successive filter elements forms respective annular sumps (<NUM>, <NUM>') for collection of coalesced liquid separated by the filter elements from the aerosol-containing gas stream as it passes radially through the nested filter elements;
the chamber has one or more inlets (<NUM>, <NUM>') in fluid communication with the or each sump for receiving the separated coalesced liquid from the sump, and further has one or more outlets (<NUM>, <NUM>') for guiding the received coalesced liquid out of the filter; and
the chamber houses a porous element (<NUM>, <NUM>') which is configured to saturate under contact with the received coalesced liquid so as to allow the received coalesced liquid to flow through the porous element to the outlet while simultaneously preventing the aerosol-containing gas stream from passing through the chamber to bypass the nested filter elements.