Patent Description:
Nasal Continuous Positive Airway Pressure (CPAP) treatment of Obstructive Sleep Apnea (OSA) was invented by Sullivan. Apparatus for treating OSA typically comprises a blower that provides a supply of air or breathable gas to a patient interface, such as a mask, via an air delivery conduit. Since patients typically sleep while wearing the device, it is desirable to have a system which is quiet and comfortable.

Blowers are typically classified as centrifugal, axial or mixed flow. Generally, blowers comprise two main parts: a rotating part, namely an impeller and shaft; and a stationary part that defines a fluid flow path, typically a chamber such as a volute. Rotation of the impeller imparts kinetic energy to the air. The stationary part redirects the air expelled from the impeller into an enclosed outlet passage. During this redirection, resistance is encountered to flow because of the pressure generated by downstream resistance or a downstream pressure source. As the flow is slowed against this resistance, a portion of the kinetic energy is converted to potential energy in the form of pressure.

Generally, the faster the impeller is rotated, the higher the pressure that will be developed. A less effective blower must rotate its impeller faster to generate the same pressure as a more effective blower. Generally, running a given blower slower makes it quieter and prolongs its life. Hence, it is generally desirable to make blowers more effective at generating a supply of air at positive pressure.

With reference to <FIG> and <FIG>, three directions are defined, i.e., radial R, tangential T and axial A. Prior art centrifugal blower <NUM> includes an outlet <NUM>, an inlet <NUM>, an electric motor <NUM>, an impeller <NUM> and a shaft <NUM>. Arrows <NUM> indicate the general direction of airflow. Air enters the blower at the inlet <NUM> and is accelerated by the rotating impeller. The rotation imparted by the impeller generally directs the airflow in a tangential direction T. The volute then constrains the airflow to spiral the volute. The airflow then exits the blower in a generally tangential direction T via the outlet <NUM>.

In some blowers, such as axially developed volute blowers, the volute geometry directs the tangential spiraling airflow in a slight axial direction A prior to exiting the blower in a generally tangential direction T.

The performance of a blower is often described using fan curves, which show the flow rate of air versus outlet pressure of air. Many factors affect the fan curve including impeller diameter and the number and shape of the impeller blades. The design process is a complex balance between competing priorities such as desired pressure, flow rate, size, reliability, manufacturability and noise. While many combinations of size, shape and configuration of components may produce a flow of pressurized air, such a result may be far from optimal, or be impractical.

Another form of known blower design is described in ResMed's International Patent Application <CIT>, published as <CIT>,. As described in this patent application, the volute geometry develops in a generally axial direction, however air exits this blower in a generally tangential direction.

Respironics International Patent Application <CIT>, published as <CIT>, describes a medical ventilator which has a blower assembly that preferably includes three rotating impellers and two stationary stators. In this device, a conventional volute design is used such that air exits the blower assembly in a generally tangential direction.

A disadvantage of this blower design is it tends to suffer from blade pass tonal noise emission.

Another known blower is found in the Respironics REMstar series of CPAP devices. In this device, air exits the blower in a generally tangential direction.

<CIT>) assigned to ResMed Limited describes a double ended variable speed blower for Continuous Positive Airway Pressure (CPAP) ventilation of patients that includes two impellers in the gas flow path that cooperatively pressurize gas to desired pressure and flow characteristics. In this device, air exits the blower in a generally tangential direction.

PCT Application Nos. <CIT>, and <CIT>, describe multiple stage blowers.

As noted above, known CPAP and VPAP blowers use a more or less conventional volute design, namely one where the air leaves the volute tangentially. These designs have the disadvantage that the asymmetry of the volute leads to asymmetry of flow patterns in the volute and impeller. This problem is especially significant at flow rates away from the ideal "design" flow rates of the volute. CPAPs and VPAPs, unfortunately, are used for a substantial portion of their operational time under non-ideal flow conditions as a consequence of very high excursions in the flow demand. This means that the flow patterns within the volute, and consequently within the impeller, become highly asymmetrical, uneven, and even unstable. This in turn leads to pressure pulses and turbulence. As a consequence, acoustic blade pass tonal noise and turbulence noise are produced.

<CIT> relates to a multiple stage variable speed blower for Continuous Positive Airway Pressure (CPAP) ventilation of patients which include two impellers in the gas flow path that cooperatively pressurize gas to desired pressure and flow characteristics.

<CIT> relates to a motor-driven centrifugal blower.

A first aspect of the invention is directed to a respiratory device that quietly and effectively provides a supply of air at positive pressure. Another aspect of the invention is to provide a blower for a NIVV device for use in treatment of a range of respiratory diseases. Another aspect of the invention is to achieve a large pressure delivery for a given motor speed. Another aspect of the invention is a blower that can supply a given pressure at a relatively low motor speed and with a fast response time. Another aspect of the invention is a blower that has reduced blade pass tonal noise emission and/or turbulence noise emission.

In one form of the invention suitable for respiratory devices, the blower is configured to provide air pressurized in the range of <NUM> H<NUM>O to <NUM> H<NUM>O. In another form suitable for treatment of Sleep Disordered Breathing, the blower is configured to provide pressure in the range of <NUM> H<NUM>O to <NUM> H<NUM>O.

In one form, the blower is configured to provide air at flow rates up to <NUM>/min. In one form, the blower is configured to provide air at flow rates ranging -<NUM>/min to +<NUM>/min.

In one form of the invention suitable for respiratory devices, the blower comprises at least one impeller having a relatively small diameter, for example in the range of <NUM> to <NUM>. In an embodiment, the impeller comprises two differently sized shrouds to provide a rigid impeller with relatively low inertia. The impeller may be injection molded from plastic such as polycarbonate or polypropylene.

An aspect of the invention is that the stationary portion of the blower defines an airflow path that is quiet and efficient. In an embodiment, the stationary portion defines an airflow path that is substantially axially symmetrical.

An aspect of the present invention has a stationary portion or volute design that is substantially axially symmetric on all stages. So no matter what the flow rate, the air feed pattern through the impeller blade passages, and in the volute, remains symmetrical and steady. This leads to lower strength pressure pulses and less turbulence, which in turn lead to lower levels of acoustic blade pass tone, and lower levels of turbulence noise.

In other forms of the invention, the blower has more than one stage. In forms of the invention where multiple stages are used along an axis, the motor may be positioned in the center and similar numbers of impellers may be positioned on either side of the motor along the axis.

In an embodiment, the stationary component of the blower includes a vane structure that receives airflow from an impeller and directs it in a radial direction. In an embodiment, the blower includes a shield positioned between an impeller and a vane structure to direct airflow to the stator inlet vanes in an orientation favorable to minimize losses and turbulence. In an embodiment, the airflow is directed in an axial direction between the impeller and vane structure. In an embodiment, the shield also presents a barrier between the impeller blades and the stator vane leading edges such that impeller blade pressure pulses are substantially isolated from the stator vanes.

Another aspect of the invention relates to a blower for supplying air at positive pressure including a stationary portion including an inlet and an outlet, a rotating portion provided to the stationary portion, and a motor adapted to drive the rotating portion. The inlet and outlet are co-axially aligned along an axis of the stationary portion such that air enters and exits the stationary portion in a generally axial direction.

Another aspect of the disclosure relates to a method for supplying air at positive pressure to a patient for treatment including providing air to a blower via an inlet that is axially aligned with an axis of the blower, directing the air through one or more stages of the blower, and supplying the air at positive pressure via an outlet that is axially aligned with the inlet.

Another aspect of the invention relates to a blower for supplying air at positive pressure including a stationary portion including an inlet and an outlet, a rotating portion provided to the stationary portion, and a motor adapted to drive the rotating portion. The stationary portion includes a shield to isolate stator vanes of the stationary portion from impeller blades of the rotating portion. The shield includes a tube portion having an interior surface and an exterior surface. The interior surface is adapted to support a bearing of the rotating portion and the exterior surface is adapted to support a stator assembly of the motor.

Other aspects, features, and advantages of this invention will become apparent from the following detailed description when taken in conjunction with the accompanying drawings, which are a part of this disclosure and which illustrate, by way of example, principles of this invention.

The accompanying drawings facilitate an understanding of the various embodiments of this invention. In such drawings:.

Aspects of the invention will be described herein in its application to non-invasive ventilation (NIVV) treatment apparatus (e.g., positive airway pressure (PAP) devices or flow generators), such as CPAP, mechanical ventilation and assisted respiration, but it is to be understood that the features of the invention will have application to other fields of application where blowers are used, such as vacuum cleaners, cooling equipment in computers and HVAC devices such as those found in buildings and vehicles.

In this specification, the words "air pump" and "blower" may be used interchangeably. In this specification, the phrase "stationary part" will be taken to include "volute". The term "air" will be taken to include breathable gases, for example air with supplemental oxygen. It is also acknowledged that the blowers described herein may be designed to pump fluids other than air.

While particular embodiments of this invention have been described, it will be evident to those skilled in the art that the present invention may be embodied in other specific forms without departing from the essential characteristics thereof. The present embodiments and examples are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing examples or description, and all changes which come. within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. It will further be understood that any reference herein to known prior art does not, unless the contrary indication appears, constitute an admission that such prior art is commonly known by those skilled in the art to which aspects of the invention relate.

A blower <NUM> according to an embodiment of the invention may be in the form of a centrifugal air pump comprising a stationary portion, a rotating portion and an electric motor.

In an exemplary embodiment as shown in <FIG>, the stationary portion includes an external housing <NUM> in two parts <NUM>, <NUM> and an assembly of internal flow directing components including three sets of stator components <NUM>, <NUM>, <NUM> and two shields <NUM>, <NUM>. The rotating portion comprises three impellers <NUM>, <NUM>, <NUM> and a shaft <NUM> adapted to be driven by electric motor <NUM>. In an embodiment, the electric motor <NUM> may be a brushless D. In the illustrated embodiment, the blower has three stages each with a corresponding impeller and set of stationary vanes and shields. As shown in <FIG> and <FIG>, the blower <NUM> is generally cylindrical and has an inlet <NUM> at one end and an outlet <NUM> at the other end.

In the illustrated embodiment, all the components of the blower are aligned along the shaft of the motor which defines an axis about which all components are generally symmetric. In an embodiment, the blower may be self similar sector-wise about its axis. This axial symmetry may apply to all stages.

An advantage of the blower according to an embodiment of the present invention is that it promotes symmetrical and stable flow patterns within the volute over the range of pressures and flow rates encountered during use. Thus, blade pass tone and turbulence noise emissions are reduced.

An advantage of the illustrated embodiment is the ease of manufacture and of assembly offered by the component geometry, particularly if injection molded, and by the stacked nature of the assembly.

The first stage of the blower will now be described. As best shown in <FIG> and <FIG>, air enters the blower <NUM> at the inlet <NUM> and passes into the first rotating impeller <NUM> where it is accelerated tangentially and directed radially outward. It then passes around the sides of the motor <NUM> flowing in a spiral manner with a large tangential velocity component and also an axial component towards the first set of stator vanes <NUM> in stator component <NUM>. In this embodiment, no shield is provided for the first stage since the shielding function is provided by the motor case. At the first set of stator vanes <NUM>, air is directed radially inwardly towards orifice <NUM>, and thereafter onto the second stage.

In the second stage, as shown in <FIG> and <FIG>, air is first accelerated tangentially by second rotating impeller <NUM> and also flows outwardly in a radial direction. Air then flows in a spiral manner with a large tangential velocity component and also an axial component passing through the gap <NUM> defined by the outer edge of circular disc <NUM> and the inner surface of the stator component <NUM>. Air then enters the second set of stator vanes <NUM> formed in stator component <NUM> and is directed radially inwardly towards orifice <NUM>, and thereafter onto the third stage.

The fluid flow path in the third stage is similar to the fluid flow path in the second stage. As shown in <FIG> and <FIG>, air enters the stage via orifice <NUM> and is accelerated tangentially and also directed outwardly in a radial direction by third rotating impeller <NUM>. Air then flows in a spiral manner with a large tangential component and also an axial component passing through the gap <NUM> defined by the outer edge of circular disc <NUM> and the inner edge of the housing <NUM>. The air then is directed by stator vanes <NUM> formed in the housing <NUM> towards the outlet <NUM>.

The stationary portion of the blower includes the two external housing parts <NUM>, <NUM>, the internal flow directing stator components <NUM>, <NUM>, <NUM> and two shields <NUM>, <NUM> and may be made from any suitable rigid or semi-rigid material that is dimensionally stable. In an embodiment, the stator component may be made from material that provides one or more of the following characteristics: good thermal conductivity; relatively low cost; low density; acoustic dampening properties; and ease of molding to reduce post machining. The use of thermally conductive material may also assist in keeping the motor cool and warming the air. The ability to heat the air may provide an additional advantage for blowers used in NIVV devices.

In an embodiment, at least some of the components of the stationary portion may be made from aluminum, or an alloy thereof, e.g., aluminum die castings. In another embodiment, at least some of the components of the stationary portion may be made from magnesium, or an alloy thereof. In yet another embodiment, at least some of the components of the stationary portion may be made from a plastic material.

The air inlet <NUM> is adapted to allow sufficient airflow into the blower to ensure desired flow requirements are met while not allowing excessive noise emission back out of the air inlet <NUM>. Also, the dimensions of the air inlet <NUM> are dependent upon the desired level of flow required by the blower and the particular application of use. In a NIVV embodiment, the air inlet <NUM> may have a diameter between <NUM> and <NUM>, e.g., between <NUM> and <NUM>.

The stator components including stator vanes are structured to promote a smooth transition in flow direction. In an embodiment, two of the stator components <NUM>, <NUM> are injection molded from a plastic (e.g., see <FIG>). The third stator component includes stator vanes <NUM> molded into the bottom casing <NUM>. In another embodiment, the stator vanes may be made using a thermally conductive material such as metal.

In an NIVV embodiment of the invention, the stator vanes direct flow in a generally radial direction. The vanes have a height in the range of <NUM> to <NUM>, e.g., <NUM> to <NUM>. This arrangement brings the flow through an approximate right angle and assists in maintaining a compact design for the blower as a whole when compared to vanes or stage-to-stage paths that include a significant axial component.

Each stage has a plurality of stator vanes to direct the airflow, e.g., between <NUM> and <NUM> stator vanes. In one embodiment, each stage has <NUM> stator vanes. Each vane is substantially identical and has a generally spiral shape with a radius of curvature that is smaller at its inner end than at its outer end, to decelerate the air before turning it too hard.

In other applications, such as ones where very high flow rates are needed. and noise is not a main consideration, the air may not be decelerated by the stator vanes.

In an alternative embodiment of the invention, the vanes may direct flow in a plane normal to the axis, or there may be an axial component to the directed flow such that at least one set of stator vanes direct flow in both radial and axial directions. In such an embodiment, the stator vanes on the final stage can be positioned on an incline or otherwise are not of constant height, but develop axially as well as radially, such that the air is turned more gradually to the axial direction. For example, <FIG> illustrate impeller <NUM> attached to motor shaft <NUM>, a shield <NUM>, and a stator <NUM> including stator vanes <NUM> structured to direct flow in both radial and axial directions. Thus, the vanes begin tangentially (as they do in the above embodiments), but end up directing the flow axially (rather than radially as in the above embodiments). This arrangement may improve pressure generation, though it takes up a little more space. This arrangement means that air does not pass through a right angle.

Another aspect of the invention relates to a shield, located between stator vanes and impeller blades (e.g., see <FIG>). In an embodiment, the shield is formed of injection molded plastic although other suitable materials (such as metals) may be used. In the illustrated embodiment, the shield extends radially beyond the outer edge of the stator vanes. This means there is not a "line-of-sight" path between the stator vanes and impeller blades and consequently acts to ensure that the airflow impinging on the stator blades is of a uniform circulating nature.

As best shown in <FIG>, <FIG>, and <FIG>, shield <NUM>, <NUM> directs the flow via an annular aperture <NUM>, <NUM>, respectively. A peripheral aperture may also be used. In one form, the shield leaves only a narrow annular gap between its outer edge and the wall of the stationary portion. The gap is sufficient to allow enough airflow to the next stage without introducing excessive pressure drop. In an embodiment for a blower for use in a NIVV device, the gap may be between <NUM> and <NUM>, e.g., between <NUM> and <NUM>. The shield also provides an acoustic barrier by isolating the impeller blade pressure pulses from the stator vanes.

In one form, the shield is a circular disc and in NIVV devices may be welded to the stator vanes.

In an alternative embodiment, the shield may rotate. Such a rotating shield may be integral to the impeller such that the lower shroud acts as a rotating shield between the impeller blades and stator vanes. For example, <FIG> illustrates impeller <NUM> attached to motor shaft <NUM>. The impeller <NUM> includes upper and lower shrouds <NUM>, <NUM> with the lower shroud <NUM> acting as a rotating shroud between impeller blades <NUM> and stator vanes <NUM> of stator <NUM>.

In contrast to the known prior art centrifugal blowers which direct air exiting the blower in a generally tangential direction, a centrifugal blower in accordance with an embodiment of the present invention directs air in a generally axial direction. This axis-symmetry is effective in reducing airflow turbulence and in reducing blade pass tone, as the impeller and vanes experience symmetrical flow patterns at all device flow rates.

The housing comprises chamfers on the external housing to assist with fitting the separate components of housing together. This design allows for an overall smaller package.

A gap between the interior wall of the external housing and the external wall of motor allows air to pass down around the sides of the motor. In an embodiment, the size of the gap is sufficient to prevent significant frictional losses but not too large that the overall size of the device becomes excessive. In an embodiment for a blower used in NIVV devices, the size of the gap may be between <NUM> and <NUM>, e.g., approximately <NUM>.

The ability of the air to flow around the motor may assist in keeping the motor cool. It may also assist in heating the patient air in an NIVV device.

In an NIVV embodiment, a blower comprises a plurality of impellers <NUM>, <NUM>, <NUM> as shown in <FIG>. In the illustrated embodiment, the impellers are identical in design, thus only impeller <NUM> will be described in detail. With particular reference to <FIG>, impeller <NUM> is of one-piece molded plastic construction, although other suitable materials and manufacturing techniques could be employed. The impeller <NUM> comprises a plurality of continuously curved blades <NUM> sandwiched between a pair of disk-like shrouds <NUM>, <NUM>. The smaller shroud <NUM> incorporates the hub or bushing <NUM> that is adapted to receive the motor shaft <NUM>. The shroud <NUM> overlaps an inner portion of the blades <NUM>, i.e., the outer diameter (OD) of the smaller shroud is substantially smaller than the OD of the larger shroud <NUM>. The larger shroud <NUM> is formed with a relatively large center opening <NUM> and extends to the radially outer tips of the blades. Making the OD of the smaller shroud <NUM> slightly smaller than the diameter of the center opening <NUM> in shroud <NUM> facilitates the molding process used to manufacture the impellers.

By utilizing differentially sized shrouds, the inertia of the impeller <NUM> is reduced while the overall rigidity of the impeller is maintained. In this regard, the impeller <NUM> may be constructed of a polycarbonate, polypropylene, polyamide, or other material which provides acoustic dampening properties that dampen the resonance of the impellers. Glass fiber reinforcement may be employed to increase the stiffness of any of these materials.

In an NIVV embodiment, the impeller <NUM> may have a diameter in the range of <NUM> to <NUM>. In one embodiment, the impeller <NUM> may have a diameter in the range of <NUM> to <NUM>, for example <NUM>. An impeller with a diameter in this range may provide a good compromise between overall size of the blower, rotational inertia, and turbulence levels.

In an NIVV embodiment, the impeller has <NUM>-<NUM> primary blades <NUM>, e.g., <NUM>. The impeller may include secondary and tertiary blades and may be of variable blade passage cross section (not shown).

In an embodiment, the impeller blades <NUM> are continuously curved in radial direction, and may also be tapered in width in the radially outer portions. The reduced width at the tips of the blades may reduce turbulence (e.g., Reynolds number is less in blowers with <NUM> impellers, <NUM> impellers, <NUM> impeller (in order)). In one embodiment, the outermost transverse edges of the blades may be stepped along their respective transverse widths (not shown) to assist in reducing turbulence noise at the tips of the blades. In another embodiment, the outermost transverse edges of the blades <NUM> are flat. In an embodiment, the blades <NUM> have an outlet height in the range of <NUM> to <NUM>, e.g., <NUM> to <NUM>. In one form, the blades <NUM> have an inlet height that is the same as the outlet height, however in other forms, the inlet and outlet heights may be different.

The blades <NUM> have an inlet angle with respect to a tangent of between <NUM>° and <NUM>°, e.g., about <NUM>°. The blades have an outlet angle with respect to a tangent between <NUM>° and <NUM>°, however other angles are possible.

In an embodiment, there is a gap between the shaft <NUM> and the shields <NUM>, <NUM>. This gap is sufficient to allow the shaft to rotate within the shields but is small enough to prevent significant leak between the impellers <NUM>, <NUM> and the internal flow directing components <NUM>, <NUM>. In a blower for a NIVV device, the gap may be less than <NUM>, e.g., less than <NUM>.

The blower according to an embodiment of the present invention comprises axially symmetric volutes, using stator vanes. The airflow enters and exits each stage within the blower in a substantially axial direction. Consequently, the air enters the blower axially at one end, and leaves it axially at the other. The airflow path is substantially axially symmetrical throughout the blower maintaining a constant feed pattern through the impeller, and in the volute. The symmetric blower provides balance, which leads to lower levels of blade pass tone, and lower levels of turbulence noise. Shields positioned between the impeller and the stator vanes provide a barrier for the vane leading edges from the impeller blade tips, thus reducing blade pass tone.

In the illustrated embodiment, the blower includes three stages with three corresponding impellers. In this embodiment, one impeller is positioned on one side of the motor and two impellers on the other side of the motor.

In an alternative embodiment, the blower may include two stages, one on either side of the motor. Another further embodiment uses four stages, with two on either side of the motor. Another embodiment is a single stage design. A further embodiment comprises multiple stages only on one side of the motor.

The following illustrates blowers according to alternative embodiments of the present invention. In each embodiment, air enters the blower axially at one end, and leaves the blower axially at the other end.

<FIG> illustrate a blower <NUM>. As illustrated, the blower <NUM> includes two stages with two corresponding impellers <NUM>, <NUM>. In this embodiment, the two impellers are positioned on the same side of the magnet <NUM> and the stator assembly <NUM> but a bearing <NUM> is positioned between the impellers <NUM>, <NUM>.

Such blower may be used in Snore PAP, CPAP, APAP, and/or VPAP and may be configured to provide a ventilator variant.

The blower <NUM> has a relatively tiny size to provide a more compact or miniature blower. For example, as shown in <FIG>, the blower <NUM> may have an overall diameter d of about <NUM>-<NUM>, e.g., <NUM>, and an overall length <NUM> of about <NUM>-<NUM>, e.g., <NUM>. However, other suitable sizes are possible.

The stationary portion of the blower <NUM> includes a housing <NUM> with first and second housing parts <NUM>, <NUM>, a stator component <NUM> including stator vanes <NUM>, and first and second shields <NUM>, <NUM>. The rotating portion of the blower <NUM> includes first and second impellers <NUM>, <NUM> adapted to be driven by motor <NUM>. The motor includes a magnet <NUM> provided to shaft <NUM> and a stator assembly <NUM> to cause spinning movement of the shaft <NUM>. In an embodiment, the motor may include <NUM> poles (for compact size), be sensorless, and/or be slotless (for low noise).

The blower <NUM> is generally cylindrical and has an inlet <NUM> provided by the first housing part <NUM> at one end and an outlet <NUM> provided by the second housing part <NUM> at the other end. As best shown in <FIG> and <FIG>, the outlet <NUM> has an annulus or ring shape. In an embodiment, the inlet may also have an annulus or ring shape (not shown).

Similar to the above embodiments, the blower <NUM> has axial symmetry and air enters the blower axially at one end and leaves the blower axially at the other end. Such arrangement may provide relatively low noise in use, e.g., due to axial symmetry and/or low volute turbulence.

As best shown in <FIG> and <FIG>, the stator component <NUM> includes a cylindrical hub <NUM> that engages within a corresponding opening <NUM> provided to the shield <NUM>, e.g., press-fit, to secure the shield <NUM> in position. In addition, the hub <NUM> provides a recess <NUM> to retain or house a bearing <NUM> that rotatably supports the shaft <NUM>. As illustrated, the bearing <NUM> is recessed into the stator component <NUM> so that it is positioned along a plane of where air is fed from the impeller <NUM>. This arrangement saves space axially because the bearing <NUM> is positioned out of the housing that encloses the motor component, i.e., stator assembly and magnet.

As best shown in <FIG> and <FIG>, the housing part <NUM> includes stator vanes <NUM> to direct flow towards the outlet <NUM>. In addition, the housing part <NUM> includes an outer annular flange <NUM> and a hub <NUM> that provides an inner annular flange <NUM> to support motor components. Specifically, the inner annular flange <NUM> retains or houses a bearing <NUM> that rotatably supports the shaft <NUM>. The outer annular flange <NUM> retains or housings the stator assembly <NUM>. The shield <NUM> engages the outer annular flange <NUM>, e.g., press-fit, to enclose the stator assembly <NUM> along with the magnet <NUM> on the shaft <NUM> within the housing part <NUM>.

In an embodiment, the housing part <NUM> may be constructed of metal so that the housing part <NUM> can act as a heat sink to conduct and dissipate heat generated from the stator assembly <NUM> in use. Also, at least a portion of the outer annular flange <NUM> supporting the stator assembly <NUM> is exposed to the flow of air, which allows cooling of the stator assembly <NUM> as air flows through the housing part <NUM> in use. However, the housing part along with other blower components may be constructed of other suitable materials, e.g., aluminum, plastic, etc..

In the illustrated embodiment, each impeller <NUM>, <NUM> includes a plurality of continuously curved or straight blades <NUM> sandwiched between a pair of disk-like shrouds <NUM>, <NUM>. The lower shroud <NUM> incorporates the hub or bushing that is adapted to receive the shaft <NUM>. Also, each impeller <NUM>, <NUM> includes a tapered configuration wherein the blades <NUM> taper towards the outer edge. Further details of impellers are disclosed in PCT Application No. <CIT>. Such arrangement may provide relatively fast pressure response, e.g., due to relatively low inertia impellers.

In the first stage, air or gas enters the blower <NUM> at the inlet <NUM> and passes into the first impeller <NUM> where it is accelerated tangentially and directed radially outward. Air then flows in a spiral manner with a large tangential velocity component and also an axial component passing through the gap <NUM> defined by the outer edge of the shield <NUM> and the inner surface of the housing part <NUM>. Air then enters the stator vanes <NUM> formed in the stator component <NUM> and is directed radially inwardly towards orifice <NUM>, and thereafter onto the second stage.

In the second stage, air or gas passes into the second impeller <NUM> where it is accelerated tangentially and directed radially outward. Air then flows in a spiral manner with a large tangential velocity component and also an axial component passing through the gap <NUM> defined by the outer edge of the shield <NUM> and the inner surface of the housing part <NUM>. Air then enters the stator vanes <NUM> formed in the housing part <NUM> and is directed towards the outlet <NUM>.

As shown in <FIG>, the blower <NUM> may be supported within an outer casing <NUM> (e.g., forming a portion of a NIVV device such as a PAP device) by a support system. The outer casing <NUM> includes a base <NUM> and a cover <NUM> provided to the base <NUM>. The support system includes a side support <NUM>, a top support <NUM>, or a bottom support <NUM> or combinations thereof to support the blower <NUM>. The support system may also be adapted to provide a seal between the inlet and the outlet sides of the blower <NUM>.

The side support <NUM> may be in the form of an annular flexible ring adapted to support the blower in a flexible and/or vibration-isolated manner within the outer casing <NUM>. In addition, the flexible ring <NUM> divides the inlet of the outer casing <NUM> from the outlet of the outer casing <NUM> to avoid the need for a connection tube that directs flow towards the outlet of the outer casing. Also, the flexible ring <NUM> may provide a seal between the base <NUM> and the cover <NUM> of the outer casing <NUM>.

The bottom support <NUM> includes a biasing member <NUM>, e.g., leaf spring, and a conducting member <NUM>. In use, the bottom support <NUM> provides a flexible structure to isolate the blower <NUM> from the outer casing <NUM>, e.g., vibration isolated. In an embodiment, the conducting member <NUM> is coupled with the stator assembly <NUM> to conduct current from an external source to the stator assembly <NUM>.

<FIG> illustrates a two-stage blower <NUM>. The two-stage blower <NUM> is similar to blower <NUM> described above. In contrast, the second housing part <NUM> and second shield <NUM> provide a different structure for supporting motor components.

As illustrated, the second housing part <NUM> includes stator vanes <NUM> to direct flow towards the outlet <NUM>. In addition, the housing part <NUM> includes a hub <NUM> that provides an annular flange <NUM>. The annular flange <NUM> is structured to engage a lower side of the stator assembly <NUM>.

The second shield <NUM> includes a tube portion <NUM> extending therefrom (e.g., integrally formed in one piece). As illustrated, the stator assembly <NUM> is provided along an exterior surface of the tube portion <NUM> such that the stator assembly <NUM> is enclosed and sandwiched between the annular flange <NUM> of the second housing part <NUM> and a tapered projection <NUM> on the shield <NUM>.

In the illustrated embodiment, the exterior surface of the stator assembly <NUM> is exposed to the flow of gas passing through the housing part <NUM>, which allows cooling of the stator assembly <NUM> in use. Also, heat from the stator assembly may be used to heat the gas for the patient without the need for a separate heater.

The interior surface of the tube portion <NUM> retains or houses a bearing <NUM> that rotatably supports the shaft <NUM>. In addition, the tube portion <NUM> encloses the magnet <NUM> on the shaft <NUM>, which is aligned with the stator assembly <NUM>. In an embodiment, the tube portion <NUM> may be "magnetically transparent", which allows the stator assembly <NUM> to act on the magnet <NUM> positioned within the tube portion <NUM> without significant loss of flux density and/or increased heat, if any. Further details of a magnetically transparent tube are disclosed in <CIT>.

A balance ring <NUM> may be optionally provided to an end portion of the shaft <NUM> (e.g., opposite the end portion supporting the impellers).

In the illustrated embodiment, the hub <NUM> protrudes further outwardly from the housing than the hub <NUM> of the blower <NUM> described above. This arrangement may add about <NUM>-<NUM>, e.g., <NUM>, to the height of the blower <NUM>, e.g., with respect to the blower <NUM>. For example, the blower <NUM> may have an overall diameter d of about <NUM>-<NUM>, e.g., <NUM>, and an overall length <NUM> of about <NUM>-<NUM>, e.g., <NUM>. However, other suitable sizes are possible.

<FIG> illustrates a three-stage blower <NUM> according to an embodiment of the present invention. Similar to the three-stage blower <NUM> described above, the blower <NUM> includes three stages with one impeller <NUM> positioned on one side of the motor <NUM> and two impellers <NUM>, <NUM> positioned on the other side of the motor <NUM>.

In the illustrated embodiment, each impeller <NUM>, <NUM>, <NUM> of the blower <NUM> has a tapered configuration. In addition, corresponding portions of the housing <NUM> and stator components <NUM>, <NUM> are tapered to match the tapered configuration of the impellers <NUM>, <NUM>, <NUM>.

In the illustrated embodiment, each impeller <NUM>, <NUM>, <NUM> includes a plurality of continuously curved or straight blades <NUM> sandwiched between a pair of disk-like shrouds <NUM>, <NUM>. The lower shroud <NUM> incorporates the hub or bushing that is adapted to receive the shaft <NUM>. Also, each impeller <NUM>, <NUM>, <NUM> includes a tapered configuration wherein the blades <NUM> taper towards the outer edge. Further details of impellers are disclosed in PCT Application No. <CIT>.

The upper wall <NUM> of the housing part <NUM> is tapered to match the tapered configuration of impeller <NUM>, and the lower wall <NUM>, <NUM> of respective stator components <NUM>, <NUM> are tapered to match the tapered configuration of impellers <NUM>, <NUM>.

Also, in the illustrated embodiment, a central portion <NUM> of the lower shield <NUM> is shaped to direct the airflow down towards the outlet <NUM>. The central portion <NUM> includes a void <NUM> along the surface facing the impeller <NUM>, e.g., to maintain a constant section/thickness for the shield <NUM> and save on material costs.

As illustrated, the bearings <NUM>, <NUM> that support the shaft <NUM> are provided within the housing <NUM> of the motor <NUM>. In an alternative embodiment, another bearing, i.e., a third bearing, may be added towards the end of the shaft <NUM> near the lower impeller <NUM> to add additional support. In another alternative embodiment, rather than adding a third bearing, one of the bearings <NUM> or <NUM> within the motor housing <NUM> may be maintained in its position and the other of the bearings <NUM> or <NUM> may be moved towards the end of the shaft <NUM> near the lower impeller <NUM> to add additional support. However, other bearing arrangements are possible.

In this embodiment, the blower <NUM> may be supported within an outer casing <NUM> (e.g., forming a portion of a NIVV device such as a PAP device) by a support system. The support system includes side supports <NUM> to support the sides of the blower <NUM> and a bottom support <NUM> to support the bottom of the blower <NUM>.

The side and bottom supports <NUM>, <NUM> may be flexible members, e.g., elastomer, to isolate the blower <NUM> from the outer casing <NUM>, e.g., vibration isolated. As illustrated, the side supports <NUM> are adapted to engage respective pegs <NUM> provided to the blower <NUM>. The bottom support <NUM> provides a conduit from the outlet <NUM> of the blower <NUM> to the outlet <NUM> of the outer casing <NUM> (e.g., which may connectable to an air delivery conduit to deliver pressurized air to a patient for therapy).

While the invention has generally been described in terms of a centrifugal pump, it is not limited to this form, and may also take the form of a mixed flow type.

An aspect of the invention is that the chamber that defines the airflow path is generally axially symmetric. This does not mean that the entire airflow path of the device that uses a blower in accordance with the invention must also be axially symmetric. Variations within the scope of the present invention may include some asymmetries. These asymmetries may lie in a region where velocities are low such that losses and noise are less affected.

In an embodiment, the blower allows the airflow feed pattern through the impeller, and in the volute, to remain symmetrical irrespective of the flow rates. This results in lower levels of blade pass tonal noise emission, and lower levels of turbulence noise emission.

Claim 1:
A centrifugal blower for a non-invasive ventilation device such as a CPAP or ventilator device, the blower (<NUM>) comprising a substantially axially symmetrical housing comprising an inlet and an outlet (<NUM>), a motor (<NUM>), a shaft (<NUM>), and at least three impellers (<NUM>, <NUM>, <NUM>) connected to the shaft (<NUM>),
wherein the blower (<NUM>) is a three-stage blower and there is at least one impeller (<NUM>, <NUM>, <NUM>) per stage;
wherein the motor (<NUM>), the at least three impellers (<NUM>, <NUM>, <NUM>), the inlet and the outlet (<NUM>) are co-axial; and
wherein the impeller (<NUM>, <NUM>, <NUM>) includes a plurality of blades (<NUM>) that taper towards an outer edge of the impeller (<NUM>, <NUM>, <NUM>).