Patent Description:
Bearings are usually employed in pairs and in coaxial arrangements to support a rotating member, e.g., motor shaft. Ideally, the two bearings are located by a stationary member that constrains the two bearings in perfect axial alignment. Real world designs are less than perfect and, therefore, compromise bearing performance.

A widely employed bearing suspension mode involves holding each bearing within a separate housing structure and fitting those housing structures together to approximate a coaxial bearing arrangement. For example, <FIG> illustrates a housing H holding bearing B1 and a cap C holding bearing B2, the cap C being fitted to the housing H to support a rotor R between the bearings B1, B2.

There are two main classes of constraints on the packaging of bearings. One constraint relates to the practical limits of manufacturing precision, and another constraint relates to the need to attach and efficiently package items that must rotate.

With respect to the first constraint, although the precision of part forming technologies improves continuously, the state of the art is far from perfect. Furthermore, increased precision usually translates to greater expense, often dissuading a manufacturer from embracing the state of the art processes.

The second constraint is driven by the need to place items (such as a rotor/stator) between bearing pairs. This leads to the use of a two part housing construction. A consequence of multipart housings is that they accumulate unwanted tolerance build-up at each faying or joint surface.

A less widely employed bearing suspension mode is to utilize a single metallic tube to house the bearing pair, and to hang the rotor from one end in cantilever fashion, i.e., an outer rotor design. For example, <FIG> illustrates a metallic tube T housing bearings B1, B2, and a rotor R supported by the bearings B1, B2 in cantilever fashion to support an impeller I. However, the metallic tube prevents a high speed magnetic rotor from being packaged between the bearings, i.e., an internal rotor design, because magnetic fields cannot effectively cross a metallic barrier without significant loss of flux density and/or increased heat. Also, there are practical limits to how much mass and length can be cantilevered from a set of high speed bearings. Therefore, such designs tend to be axially short in length.

Thus, a need has developed in the art for an improved arrangement that does not suffer from the above-mentioned drawbacks.

<CIT> relates to a silent pump module having a housing and a pump, wherein the pump is mounted into the housing, the housing comprises an interior wall and an exterior wall, wherein there is a a space between the interior wall and the exterior wall, in which the gas pressure is lower than the ambient air pressure.

<CIT> relates to a radial compressor for respiration purposes. The sound emissions generated by deflections and separations of the gas flow in the compressor wheel and the housing of the radial compressor and by the high-speed motor of the radial compressor are reduced. This is achieved with a specially shaped passage channel for the volume flow, which exerts a stabilizing effect on the volume flow utilizing the Bernoulli principle of flow. Additional sound reduction is provided by using a separate mass arranged between the motor and the housing, which absorbs the sound energy generated by the high-speed motor. Also sound reduction is provided by suspending the radial compressor with membranes in a closed capsule.

<CIT> relates to a vibration-generating small motor and portable electronic apparatus.

<CIT> relates to a machine installation.

<CIT> relates to a motor pump unit and cooling means.

<CIT> relates to gas forwarding apparatus for respiration and narcosis devices.

One aspect of the invention relates to a rotor supporting structure to support a rotor in use.

Another aspect relates to a bearing arrangement having at least two bearing portions supported on a common member, e.g., bearing tube.

Another aspect relates to a brushless DC motor with bearings retained in a stationary tube having at least a portion that is sufficiently magnetically transparent to allow a magnetic field to pass through it, e.g., non-electrically conductive and/or non-magnetic tube. In the context of an embodiment of the invention, a non-conductive material may be a material with relatively high resistivity (for example, in the vicinity of <NUM> micro Ohm-m or more) and a non-magnetic material may be a material with relatively low magnetic permeability (for example, in the vicinity of <NUM> or less). The acceptable ranges of these material characteristics may vary from case to case. The tube may be generally thermally conductive, and such tube can be metallic and/or non-metallic or semi-metallic.

Another aspect relates to a brushless DC motor including a rotor, a magnet provided to the rotor, a pair of bearings to rotatably support the rotor, a stator assembly that at least partly surrounds the rotor and magnet thereof, and a bearing tube having an exterior surface and an interior surface that defines a tube interior. The stator assembly is adapted to control movement of the rotor. The stator assembly is provided along the exterior surface of the tube and the bearings are provided along the interior surface of the tube to support the rotor and magnet within the tube interior. The tube has at least a portion that is sufficiently magnetically transparent to allow a magnetic field to pass between the magnet and the stator assembly.

Another aspect relates to a brushless DC motor including a rotor having a magnet, a stator assembly adapted to control movement of the rotor, and a tube provided between the rotor and the stator assembly. The tube has at least a portion that is sufficiently magnetically transparent to allow a magnetic field to pass between the magnet and the stator assembly.

Another aspect relates to a brushless DC motor including a magnetic rotor rotatably supported between a pair of bearings, a stator assembly surrounding the rotor and adapted to control movement of the rotor, and a tube to retain the bearings and rotor within an interior of the tube. The tube has at least a portion that is sufficiently magnetically transparent to allow a magnetic field to pass between the magnetic rotor and the stator assembly.

Another aspect of the invention relates to a PAP device for generating a supply of pressurized gas to be provided to a patient for treatment. The PAP device includes a housing, a core including a motor and at least one impeller, and a vibration isolation system to support the core within the housing in a flexible, vibration-isolated manner.

Another aspect of the invention relates to a PAP device for generating a supply of pressurized gas to be provided to a patient for treatment. The PAP device includes a housing, a core including a motor and at least one impeller, and a vibration isolation system to support the core within the housing in a flexible, vibration-isolated manner. The vibration isolation system is adapted to be coupled to windings of a stator assembly to conduct current from an external source to the windings.

Another aspect of the invention relates to a brushless DC motor including a rotor, a stator assembly surrounding the rotor and adapted to control movement of the rotor, a support structure to support the rotor and the stator assembly in an operative position, and a vibration isolation system provided to the support structure and adapted to support the support structure within a housing in a flexible, vibration-isolated manner.

Another aspect relates to a method for manufacturing a motor. The method includes forming a tube having at least a portion that is sufficiently magnetically transparent to allow a magnetic field to pass through it, providing a magnetic rotor to an interior portion of the tube, and providing a stator assembly to an exterior portion of the tube to control movement of the magnetic rotor.

Another aspect relates to a rotor supporting structure including at least one bearing support portion adapted to support a bearing and a sufficiently magnetically transparent portion to allow a magnetic field to pass through it.

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 the invention.

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

The following description is provided in relation to several embodiments which may share common characteristics and features.

The term "air" will be taken to include breathable gases, for example air with supplemental oxygen. It is also acknowledged that the PAP devices described herein may be designed to pump fluids or gases other than air.

<FIG> illustrates an electric motor or tube motor <NUM>. In the illustrated embodiment, the motor <NUM> is in the form of a brushless DC motor. The motor <NUM> includes an optional housing <NUM>, a rotatable shaft or rotor <NUM>, a permanent magnet <NUM> mounted on the rotor <NUM>, and a stator assembly <NUM> that surrounds the rotor <NUM> and magnet <NUM> thereof. The rotor <NUM> is rotatably supported by a pair of bearings <NUM> that are retained or housed by a bearing tube <NUM>. The bearings <NUM> may be any suitable type as known in the art, e.g., conventional rolling element bearings, fluid bearings (air or liquid), sleeve bearings, or other type.

The optional housing <NUM> encloses the stator assembly <NUM>, rotor <NUM>, magnet <NUM>, bearings <NUM>, and bearing tube <NUM>. An end cap <NUM> is provided to the housing <NUM> to allow access to the housing interior and the components enclosed therein. In addition, the end cap <NUM> and end wall <NUM> of the housing each include an opening <NUM> to allow respective end portions <NUM>, <NUM> of the rotor <NUM> to extend therethrough. Each end portion <NUM>, <NUM> is adapted to be coupled to a device, e.g., impeller, to cause spinning movement of the device. However, the motor <NUM> may be structured such that only one end portion of the rotor <NUM> extends from the housing <NUM>. In use, an electronic controller (typically provided as part of PAP devices or flow generators available from ResMed) controls operation of the stator assembly <NUM> to control spinning movement of the rotor <NUM> and hence the device, e.g., impeller.

In the illustrated embodiment, the bearing tube <NUM> comprises a relatively thin-walled, stationary, stable tube.

The bearing tube <NUM> has at least a portion that is sufficiently magnetically transparent tq allow a magnetic field to pass through it. In an embodiment, such "magnetic transparency" may be provided by one or more the tube's material properties, e.g., non-electrically conductive, magnetically transparent or non-magnetic, and/or thermally conductive tube. Alternatively, such "magnetic transparency" may be provided by one or more perforations in the tube as described in greater detail below.

In some applications, it may not be necessary for the tube to have all the material properties described above (non-electrically conductive, magnetically transparent, and thermally conductive) as the tube may simply include one or more of these properties and/or a sufficient degree of these properties (e.g., partially electrically conductive and/or partially heat conductive). In addition, non-conductive refers to the (non)conduction of electricity, although the tube <NUM> may be heat conductive in embodiments, which may be beneficial for warming the air and/or cooling the blower elements. The tube includes adequate "magnetic transparency", "non-electrical conductivity", and/or "thermal conductivity" to allow sufficient magnetic flux near the magnet without overheating.

In the context of an embodiment of the invention, a non-conductive material is understood to be a material with relatively high resistivity (for example, in the vicinity of <NUM> micro Ohm-m or more) and a non-magnetic material is understood to be a material with relatively low magnetic permeability (for example, in the vicinity of <NUM> or less). The acceptable ranges of these material characteristics may vary, e.g., depending on application.

The tube may be thermally conductive to allow heat release (heat may create drag on motor, inefficient power, reduced life on bearings, tube distortion, etc.).

In addition, the tube may have different material properties along its length or circumference, e.g., different levels or regions of "magnetic transparency", "non-electrical conductivity", and/or "thermal conductivity. " That is, portions of the tube may have one or more of these properties, but other portions of the tube may not.

Magnetic transparency should be greater in the vicinity of the magnet and stator assembly, where flux densities may be expected to be higher. Outside of that region, different properties could be tolerated and in some cases may not be necessary. For example, it could be advantageous to construct the tube from different elements that are fastened together, wherein some of the elements are magnetically transparent, in locations where that is desirable, and other elements of the tube are more thermally conductive, for example.

The bearing tube <NUM> may be constructed of non-metallic materials, e.g., ceramics (e.g., stabilized zirconia), glass, polymers, filled (but non-conductive) polymers, or reinforced polymers (e.g., Fiberglass, Carbon, Boron, etc.). However, the tube can also be metallic or semi-metallic. In an embodiment, the tube may include different materials along its length or circumference.

In the illustrated embodiment, the tube has a circular cross-sectional configuration along its length. However, it should be appreciated that the tube may have other suitable shapes, e.g., circular or round, square, polygonal, conical, etc..

Also, the tube may include one or more parts (e.g., multi-part construction), e.g., different elements with different properties that are fastened together.

In an embodiment, the tube may be sufficiently perforated (e.g., one or more holes, openings, and/or slits) to allow a magnetic field to pass through it. In such embodiment, the tube may or may not include non-electrically conductive, magnetically transparent, and/or thermally conductive material properties.

Also, it should be understood that portions of the tube may have one or more of the features described above, but other portions of the tube may not.

As illustrated, the stator assembly <NUM> is provided to a center portion <NUM> of the tube <NUM> along an exterior surface <NUM> thereof. The bearings <NUM> are provided to respective end portions <NUM>, <NUM> of the tube <NUM> along an interior surface <NUM> thereof. The tube <NUM> retains the bearings <NUM> in substantially perfect axial alignment. The bearings <NUM> support the rotor <NUM> and magnet <NUM> within the tube interior. In addition, the magnet <NUM> is positioned between the bearings <NUM> such that the magnet <NUM> is aligned with the stator assembly <NUM>.

The inside diameter of the tube <NUM> is substantially similar to the outside diameter of the bearings <NUM>. This allows the bearings <NUM> to be securely and stably retained within the tube <NUM>, e.g., by friction fit, adhesive, etc..

The tube <NUM> is sufficiently "magnetically transparent" (e.g., non-magnetic, non-electrically conductive, and/or thermally conductive), which allows the motor <NUM> to have a design in which the magnetic rotor <NUM> is located between the bearings <NUM> within the tube <NUM>, as illustrated in <FIG>. That is, the stator assembly <NUM> can act on the magnetic rotor <NUM> positioned within the tube <NUM> without significant loss of flux density and/or increased heat, if any. Thus, the tube <NUM> provides stable physical properties and is adequate to support the needs of the motor application. It is noted that the bearing tube <NUM> may be incorporated into other motor arrangements or other applications where "magnetic transparency" may be beneficial.

The motor arrangement of <FIG>, in which the magnetic rotor <NUM> is positioned within the "magnetically transparent" tube, <NUM> has several advantages. For example, the motor arrangement provides superior bearing-to-bearing alignment. The superior alignment results in improved noise and/or improved life. In addition, the superior alignment results in the ability to better accommodate fluid bearings, e.g., when the materials of the rotor and the tube have closely matched thermal expansion coefficients (e.g., both the tube and rotor may be made of stabilized zirconia).

The motor arrangement also provides superior compactness (e.g., the rotor may reside between the tube mounted bearings, not cantilevered), superior dynamic response due to an inherently low inertia rotor, and superior rigidity due to simplicity of construction. In addition, the motor arrangement provides superior accommodation of both fluid bearings and a double-ended, impeller blower construction (e.g., when the motor is incorporated into a PAP device or flow generator as described below).

Further, when rolling element bearings are used, matched thermal coefficients of the tube and rotor may allow one to eliminate a preload spring. Specifically, one method for assembling bearings includes using a preload spring that applies a force to the bearings to ensure they remain correctly aligned and retained in position against the ends of tube, e.g., against flange <NUM> for the lower bearing and against tapered flange <NUM> for the upper bearing as shown <FIG>. As an alternative to such method, the preload spring may be eliminated and the bearings may be retained in position by an adhesive, e.g., glue, or other suitable fixing means, e.g., mechanical fasteners, etc. The bearings may be of a range of varieties. For example, the bearings could be constructed as sleeve types, duplex types, magnetic types, etc..

Such an alternative method is illustrated in <FIG>. In such method, a force may be applied (e.g., by spring <NUM> as indicated in dashed lines) to force the bearings <NUM>, <NUM> against respective flanges <NUM>, <NUM> and in correct alignment. Once aligned, an adhesive A, e.g., glue, or other fixing means may be applied between the bearings <NUM>, <NUM> and the tube <NUM> to fix and retain the bearings <NUM>, <NUM> in position while the force is being applied, e.g., by the spring <NUM>. Once the bearings <NUM>, <NUM> are fixedly attached, the force may be removed.

A potential problem with this alternative method is that when the motor warms up, different components (e.g., such as the rotor and the tube) will expand according to their individual thermal expansion coefficient which relates to the material used to make the components. Thus, if the rotor and the tube materials have two different thermal expansion coefficients allowing them to expand at different levels, the bearings may move or misalign causing an imbalance in the motor. In order to prevent such problems from occurring, the tube and the rotor may be made from the same material to have the same thermal expansion coefficient or the tube and the rotor may be made from two different materials with the same thermal expansion coefficient.

The motor <NUM> may be incorporated into a PAP device or flow generator structured to generate a supply of pressurized gas to be provided to a patient for treatment, e.g., of Sleep Disordered Breathing (SDB) with Non-Invasive Positive Pressure Ventilation (NIPPV). In an embodiment, the motor may be constructed to operate up to about <NUM>,<NUM> rpm and/or <NUM> mNm torque.

For example, <FIG> is a schematic view of a PAP device or flow generator <NUM> including the motor <NUM>. As illustrated, the PAP device <NUM> includes a housing <NUM> and a blower <NUM> supported within the housing <NUM>. The blower <NUM> is operable to draw a supply of gas into the housing <NUM> through one or more intake openings (not shown, but typically provided at the bottom or side wall of the flow generator housing) and provide a pressurized flow of gas at an outlet <NUM>. The supply of pressurized gas is delivered to the patient via an air delivery conduit that includes one end coupled to the outlet <NUM> of the PAP device <NUM> and an opposite end coupled to a mask system that comfortably engages the patient's face and provides a seal. In an embodiment, the blower is constructed to deliver pressurized gas suitable for CPAP or NIPPV, e.g., in the range of <NUM>-<NUM> cmH<NUM>O, at flow rates of up to <NUM>/min (measured at the mask), depending on patient requirements. Also, the blower may be configured to deliver bilevel therapy or variable pressure therapy (e.g., low range of <NUM>-<NUM> cmH<NUM>O and high range of <NUM>-<NUM> cmH<NUM>O).

The blower <NUM> is supported by or within the housing <NUM>, and includes at least one impeller <NUM> and the motor <NUM> to drive the at least one impeller <NUM>. In the illustrated embodiment, the blower <NUM> has a double-ended, impeller blower construction. Specifically, the motor <NUM> includes the arrangement shown in <FIG>, and each end portion <NUM>, <NUM> of the rotor <NUM> is coupled to an impeller <NUM>. However, the blower <NUM> may include a single impeller coupled to the motor <NUM>.

The motor may incorporated into blower assemblies such as those disclosed in <CIT>, <CIT>, and <CIT>, and <CIT>.

Also, the motor <NUM> may be employed in other applications.

A PAP device or flow generator <NUM> including the motor arrangement of <FIG> has several advantages. For example, the motor arrangement of <FIG> provides a quieter, longer life, smaller, more reliable, and highly responsive PAP device. This provides a PAP device that is more comfortable and easier to use for the patient. Because the patients are more satisfied, therapy is easier to administer for the physician.

In addition, the PAP device <NUM> including the motor arrangement of <FIG> provides a potentially lower cost due to reduced parts count and less machining, a superior motor platform for implementing conventional rolling element bearings, a motor platform to accommodate fluid bearings, a motor platform to accommodate fluid bearings and a double-ended, impeller blower construction, and/or a motor platform to accommodate fluid bearings and a double-ended, impeller blower construction and integral volutes and/or blower housings.

<FIG> and <FIG> illustrate an electric motor or tube motor <NUM>. The tube motor <NUM> is substantially similar to the tube motor <NUM> described above, and also illustrates the motor's ability to function as a motor without the requirement of a housing or endcap.

As illustrated, the motor <NUM> includes a rotatable shaft or rotor <NUM> including a permanent magnet <NUM> provided thereto, a "magnetically transparent" bearing tube <NUM> structured to retain or house bearings <NUM> that rotatably support the rotor <NUM> within the tube <NUM>, and a stator assembly <NUM> provided along an exterior surface of the tube <NUM> (e.g., retained on tube by friction).

In the illustrated embodiment, the stator assembly <NUM> includes windings <NUM>, a stator or stator lamination stack <NUM> provided to the windings <NUM>, and one or more insulators <NUM> provided between the windings <NUM> and the stack <NUM> to insulate the stack <NUM> from the windings <NUM>. As described above, the tube <NUM> is "magnetically transparent", which allows the stator assembly <NUM> to act on the magnetic rotor <NUM> positioned within the tube <NUM> without significant loss of flux density and/or increased heat, if any.

A spacer <NUM> is provided between the rotor magnet <NUM> and one of the bearings <NUM>, and a spring or biasing element <NUM> is provided between the rotor magnet <NUM> and the other of the bearings <NUM>. This arrangement maintains alignment of the rotor magnet <NUM> with the stator assembly <NUM>.

In the "tube motor" described herein, the housing elements are replaced by a single tube <NUM> that extends through the core of the stator assembly <NUM>. The tube <NUM> is thin-walled (but strong) and is "magnetically transparent", which allows the bearings to be mounted within a single bore with the rotor magnet nested therebetween. The rotor's magnetic flux penetrates the wall of the tube (since the tube is "magnetically transparent") to interact with stator winding currents to produce shaft torque.

Thus, the "tube motor" is self-contained wherein the stator and rotor are supported and/or contained by the tube in a manner that allows the tube motor to function as a motor. That is, a housing or endcap is not needed to support and/or contain the stator and/or rotor, e.g., housing not needed to support motor bearings. PAP devices, a housing and/or endcap may be provided to the tube motor to define a plenum chamber for pressurized gas.

Benefits and features of the tube motor <NUM> include one or more of the following:.

Reduction or elimination in tolerances by using the tube (e.g., no tolerance may be required for the stator from the rotor/stator alignment).

It should be appreciated that the motors <NUM>, <NUM> may include one or more similar advantages, benefits and/or features.

<FIG> illustrate a PAP device or blower <NUM>. As illustrated, the PAP device <NUM> includes a volute or housing <NUM> that defines a generally spiral-shaped channel <NUM>, a tube motor <NUM> including a "magnetically transparent" tube <NUM> support by or within the housing <NUM>, an impeller <NUM> provided to the rotor <NUM> of the tube motor <NUM>, and a lid or end cap <NUM> provided to the housing <NUM> to enclose the impeller <NUM>.

As best shown in <FIG>, the PAP device <NUM> is operable to draw a supply of gas into the housing through an inlet <NUM> and provide a pressurized flow of gas at an outlet <NUM>. The PAP device <NUM> is generally cylindrical with the inlet <NUM> aligned with an axis of the PAP device and the outlet <NUM> structured to direct gas exiting the PAP device in a generally tangential direction.

In an embodiment, the PAP device <NUM> may have a diameter of about <NUM> and a height of about <NUM>, which provides a cylindrical volume of about <NUM><NUM>. The outlet <NUM> may have a diameter of about <NUM>. It is to be understood that these dimensions are merely exemplary and other dimensions are possible depending on application.

The tube motor <NUM> includes a rotatable shaft or rotor <NUM> including a permanent magnet <NUM> provided thereto, a "magnetically transparent" tube <NUM> structured to retain or house bearings <NUM>, <NUM> that rotatably support the rotor <NUM> within the tube <NUM>, and a stator assembly <NUM> provided along an exterior surface of the tube <NUM> (e.g., retained on tube by friction).

The stator assembly includes windings <NUM>, a stator or stator lamination stack <NUM> (e.g., slotless or toothless) provided to the windings <NUM>, and one or more insulators <NUM> provided between the windings <NUM> and the stack <NUM> to insulate the stack <NUM> from the windings <NUM>. Further details of coil winding is disclosed in <CIT>.

The tube <NUM> of the tube motor <NUM> includes a tube portion <NUM>, a shield <NUM> provided to one end of the tube portion <NUM>, and an annular flange <NUM> extending from the shield <NUM>. In the illustrated embodiment, the tube <NUM> is integrally molded (e.g., injection molded) as a one-piece structure. However, the tube <NUM> may be constructed in other suitable manners.

The tube portion <NUM> of the tube <NUM> is structured to retain and align the bearings <NUM>, <NUM> that rotatably support the rotor <NUM>. In the illustrated embodiment, the tube portion <NUM> is structured such that mixed bearing sizes may be used.

As illustrated, the upper end of the tube portion <NUM> is structured to support bearing <NUM> and the lower end of the tube portion <NUM> is structured to support bearing <NUM> having a smaller size or diameter than bearing <NUM>.

Specifically, the upper end of the tube portion <NUM> includes an annular surface <NUM> defining a diameter D and adapted to support bearing <NUM>. The lower end of the tube portion <NUM> includes an annular surface <NUM> defining a smaller diameter d and adapted to support bearing <NUM>. As illustrated, the one-piece tube portion <NUM> provides accurate bore-to-bore alignment which provides accurate bearing-to-bearing alignment. The upper end of the tube portion <NUM> also includes one or more extensions <NUM> structured to strengthen the upper end of the tube portion <NUM> supporting the bearing <NUM>.

In an embodiment, the tube portion may be manufactured such that substantially no draft angle is provided along surfaces <NUM>, <NUM> adapted to support respective bearings <NUM>, <NUM>. However, a draft angle may be provided along the surface between surfaces <NUM> and <NUM> to facilitate molding along the line of draw.

A sloped surface <NUM> may be provided between surfaces <NUM>, <NUM> to guide the rotor <NUM> (with bearings <NUM>, <NUM> provided to respective end portions) into the lower end of the tube portion <NUM>. For example, the smaller bearing side of the rotor <NUM> may be inserted into or "dropped into" the tube portion <NUM> through the upper end of the tube portion <NUM>. As the smaller bearing <NUM> approaches the lower end, the sloped surface <NUM> will guide the bearing <NUM> into engagement with surface <NUM> having a reduced diameter. Thus, the bearing <NUM> is self-guided into its operative position.

In the illustrated embodiment, the lower end of the tube portion <NUM> includes a flange <NUM> that provides a stop or support for the bearing <NUM> at the lower end. Also, the upper end of the tube portion <NUM> includes one or more tapered flange portions <NUM> adapted to engage the bearing <NUM>, and hence retain the rotor within the tube portion <NUM>.

The tapered flange portions <NUM> provide snap-in bearing retention. That is, the tapered flange portions <NUM> may be resiliently deflected upon rotor assembly to allow the bearing <NUM> to snap into the tube portion <NUM>, but prevent removal of the bearing <NUM> (and hence the rotor) from the tube portion <NUM> once assembled.

A spring or biasing element <NUM> may be provided between the bearing <NUM> and the rotor magnet <NUM> to maintain alignment of the rotor magnet <NUM> with the stator assembly <NUM>.

The shield <NUM> of the tube <NUM> forms an upper wall or cutoff for the channel <NUM> that directs pressurized gas to the outlet <NUM>. In the illustrated embodiment, the shield <NUM> is in the form of a circular disk that is provided to (e.g., integrally formed in one-piece) an end of the tube portion <NUM> adjacent the impeller <NUM>.

In the illustrated embodiment, the outer edge of the shield <NUM> substantially aligns with or extends radially beyond the outer edge of the impeller <NUM>. The shield <NUM> provides a narrow annular gap <NUM> (e.g., about <NUM>) between its outer edge and the wall of the housing <NUM>, which is sufficient to direct gas into the channel <NUM> leading to the outlet <NUM>.

The tube motor <NUM> and the housing <NUM> provide complementary structural elements that are adapted to support, align, and/or contain the tube motor <NUM> within the housing <NUM>.

In the illustrated embodiment, the housing <NUM> includes one or more slots <NUM> in an upper portion of the housing wall that is adapted to receive respective tabs <NUM> provided along the outer edge of the shield <NUM> (e.g., see <FIG>). In an embodiment, the shield <NUM> includes three tabs <NUM> that are received in respective slots <NUM> of the housing <NUM>. However, any suitable number of slots/tabs may be provided.

The housing <NUM> and tube <NUM> cooperate to support and maintain the stator assembly <NUM> in an operative position. As illustrated in <FIG> and <FIG>, the annular flange <NUM> of the tube <NUM> is structured to enclose an upper portion of the windings <NUM> and engage an upper side of the stack <NUM>. Similarly, the bottom wall of the housing <NUM> includes an annular flange <NUM> that is structured to enclose a lower portion of the windings <NUM> and engage a lower side of the stack <NUM>. Thus, the annular flanges <NUM>, <NUM> cooperate to enclose and sandwich the stator assembly <NUM> between the housing <NUM> and the tube <NUM>.

Also, each flange <NUM>, <NUM> includes one or more anchoring protrusions <NUM> (also referred to as anchoring pips or locating pins) that are adapted to engage within corresponding holes <NUM> provided through the stack <NUM>. This arrangement self-adheres and/or aligns the housing <NUM> and the tube <NUM> to the stack <NUM>. In the illustrated embodiment, exterior surfaces of the flanges <NUM>, <NUM> are substantially flush with an exterior surface of the stack <NUM>.

In addition, the bottom wall of the housing <NUM> includes an opening <NUM> adapted to receive the lower end of the tube portion <NUM> of the tube <NUM>. One or more tabs <NUM> may be provided along the edge of the opening <NUM> that are adapted to engage within respective openings <NUM> provided in the lower end of the tube portion <NUM>.

In an embodiment, the above-described complementary structural elements provided to the tube motor <NUM> and the housing <NUM> may provide snap-fit retention.

In the illustrated embodiment, the PAP device <NUM> includes a single impeller <NUM>. As illustrated, the impeller <NUM> includes a plurality of continuously curved or straight 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 an end portion of the rotor <NUM>. Further details of impellers are disclosed in PCT Application No. <CIT>.

This arrangement provides a low cost and low inertia alternating shroud impeller. In an embodiment, a gap G (e.g., see <FIG>) may be controlled by a press-to-shim technique. For example, a shim <NUM> may be provided along the upper end of the tube <NUM> that is adapted to engage the lower end of the hub <NUM> of the impeller <NUM> (as the hub <NUM> is mounted to the rotor <NUM>) and hence control the size of the gap G.

In an embodiment, the impeller <NUM> may have a diameter of about <NUM>. It is to be understood that this dimension is merely exemplary and other dimensions are possible depending on application.

As shown in <FIG>, a balance ring <NUM> may be optionally provided to an opposite end portion of the rotor <NUM> (opposite the end portion supporting the impeller <NUM>).

This arrangement may facilitate single-plane or two-plane balancing of the tube motor <NUM>.

As best shown in <FIG>, gas enters the PAP device at the inlet <NUM> and passes into the impeller <NUM> where it is accelerated tangentially and directed radially outward. The gap <NUM> between the outer edge of the shield <NUM> and the wall of the housing <NUM> allows gas to pass into the channel <NUM> and down around the sides of the tube motor <NUM>. Gas passes around the channel <NUM> and the sides of the tube motor <NUM> flowing in a spiral manner with towards the outlet <NUM>.

In the illustrated embodiment, the exterior surface of the stack <NUM> of the stator assembly <NUM> is exposed to the channel <NUM> of the housing <NUM> and hence is exposed to the gas passing through the channel <NUM>. This arrangement allows forced-convection cooling of the stack <NUM> as gas flows through the channel <NUM> in use.

The PAP device <NUM> includes a relatively basic construction with a single impeller to provide relatively basic CPAP and/or SnorePAP treatment.

In addition, the PAP device <NUM> provides four plastic molded (e.g., injection-molded) parts, i.e., the housing <NUM>, the tube <NUM>, the impeller <NUM>, and the end cap <NUM>. These molded parts (along with the rotor <NUM>, stator assembly <NUM>, bearings <NUM>, <NUM>, and spring <NUM>) provide an arrangement with relatively low component and assembly costs.

<FIG> illustrate a PAP device or blower <NUM> (e.g., to provide CPAP through BiLevel NIV treatment) according to another embodiment of the present invention. In this embodiment, the PAP device <NUM> includes a housing <NUM> and a core <NUM> supported within the housing <NUM> by a vibration isolation system <NUM>. As described in greater detail below, the vibration isolation system <NUM> supports the core <NUM> in a flexible, vibration-isolated manner with respect to the housing <NUM> so that the core <NUM> is substantially isolated from the housing <NUM>. Thus, vibrations and/or other movement generated by the core <NUM> in use are substantially isolated from the housing <NUM>.

In the illustrated embodiment, the core <NUM> includes a tube motor <NUM> including a "magnetically transparent" tube <NUM>, a core housing <NUM> structured to substantially enclose the tube motor <NUM>, an impeller <NUM> provided to one end portion of the rotor <NUM> of the tube motor <NUM>, and a balance ring <NUM> provided to an opposite end portion of the rotor <NUM>.

As described above, the tube motor <NUM> includes a rotatable shaft or rotor <NUM> including a permanent magnet <NUM> provided thereto, a "magnetically transparent" tube <NUM> structured to retain or house bearings <NUM> that rotatably support the rotor <NUM> within the tube <NUM>, and a stator assembly <NUM> provided along an exterior surface of the tube <NUM> (e.g., retained on tube by friction).

The stator assembly <NUM> includes windings <NUM>, a stator or stator lamination stack <NUM> (e.g., slotless or toothless) provided to the windings <NUM>, and one or more insulators <NUM> provided between the windings <NUM> and the stack <NUM> to insulate the stack <NUM> from the windings <NUM>.

A spring or biasing element <NUM> may be provided between one of the bearings <NUM> and the rotor magnet <NUM> to maintain alignment of the rotor magnet <NUM> with the stator assembly <NUM>.

In the illustrated embodiment, the core housing <NUM> includes a first housing part <NUM> provided to one end of the tube <NUM> and a second housing part <NUM> provided to the opposite end of the tube <NUM>.

As illustrated, the first housing part <NUM> includes a shield <NUM> that forms an upper wall or cutoff for the housing channel <NUM>. An inner annular flange <NUM> and an outer annular flange <NUM> extend from the shield <NUM>. In the illustrated embodiment, the shield <NUM> and impeller <NUM> have a tapered or sloped configuration along its radial length. However, other suitable configurations of the shield and impeller are possible.

As described above, the shield <NUM> provides a narrow annular gap <NUM> between its outer edge and the housing <NUM>, which is sufficient to direct gas into the housing channel <NUM>.

The shield <NUM> includes an opening that allows one end portion of the rotor <NUM> to pass therethrough. The edge of the opening includes an annular slot <NUM> that is adapted to receive one end of the tube <NUM>.

Also, the inner annular flange <NUM> is structured to enclose an upper portion of the windings <NUM> and engage an upper side of the stack <NUM>. The inner annular flange <NUM> includes one or more anchoring protrusions <NUM> that are adapted to engage within corresponding holes <NUM> provided through the stack <NUM>.

The second housing part <NUM> includes a main wall <NUM> and an annular flange <NUM> extending from the main wall <NUM>. The main wall <NUM> includes an opening that allows the opposite end portion of the rotor <NUM> to pass therethrough. The edge of the opening includes an annular slot <NUM> that is adapted to receive the opposite end of the tube <NUM>.

Also, the annular flange <NUM> is structured to enclose a lower portion of the windings <NUM> and engage a lower side of the stack <NUM>. The annular flange <NUM> includes one or more anchoring protrusions <NUM> that are adapted to engage within corresponding holes <NUM> provided through the stack <NUM>.

Thus, the flanges <NUM>, <NUM> cooperate to enclose and sandwich the stator assembly <NUM>. In the illustrated embodiment, exterior surfaces of the flanges <NUM>, <NUM> are substantially flush with an exterior surface of the stack <NUM>, i.e., exterior surface of stack exposed. As described above, this arrangement allows forced-convection cooling of the stack <NUM> as gas flows through the housing channel <NUM> in use.

The core housing <NUM> also includes a cap <NUM> provided to the second housing part <NUM> and adapted to enclose the balance ring <NUM> at one end portion of the rotor <NUM>.

In an alternative embodiment, one or portions of the core housing <NUM> may be integrally formed in one piece with the tube <NUM>, e.g., similar to tube <NUM> described above.

The housing <NUM> includes a main body <NUM> that provides an outer wall for the housing channel <NUM> and a lid or end cap <NUM> provided to the main body <NUM> to enclose the core <NUM>.

As best shown in <FIG> and <FIG>, the PAP device <NUM> is operable to draw a supply of gas into the housing through an inlet <NUM> and provide a pressurized flow of gas at an outlet <NUM>. The PAP device <NUM> is generally cylindrical with the inlet <NUM> aligned with an axis of the PAP device and the outlet <NUM> structured to direct gas exiting the PAP device in a generally tangential direction.

The vibration isolation system <NUM> includes a front suspension <NUM> (or front vibration isolator) to support a front portion of the core <NUM> and a rear suspension <NUM> (or rear vibration isolator) to support a rear portion of the core <NUM>. The front and rear suspension <NUM>, <NUM> together support the core <NUM> in a flexible, vibration-isolated manner with respect to the housing <NUM>.

The front suspension <NUM> includes a plurality of biasing elements <NUM>, e.g., flat springs. As best shown in <FIG>, each biasing element <NUM> includes one end portion <NUM>(<NUM>) provided to the outer annular flange <NUM> of the shield <NUM> of the core <NUM>, an opposite end portion <NUM>(<NUM>) provided to the main body <NUM> of the housing <NUM>, and an intermediate portion <NUM>(<NUM>) that provides a flexible structure to isolate the core <NUM> from the housing <NUM>.

In the illustrated embodiment, the one end portion <NUM>(<NUM>) includes a bent configuration adapted to receive the free end of the flange <NUM>. The opposite end portion <NUM>(<NUM>) includes a bent configuration adapted to engage within a slot <NUM> provided to the main body <NUM>. The intermediate portion <NUM>(<NUM>) is bent into a concertina or bellow-like configuration to provide a flexible structure.

In use, the biasing elements <NUM> support the front portion of the core <NUM> within the housing <NUM> while isolating the core <NUM> from the housing <NUM>, e.g., vibration isolated.

In addition, wire W from the windings <NUM> may be coupled to one or more of the biasing elements <NUM>, e.g., wire W connected to the end portion <NUM>(<NUM>). This allows the biasing elements <NUM> (e.g., flat springs formed of metal) to conduct current from an external source to the windings <NUM>. For example, <FIG> and <FIG> illustrate external source S that may be coupled to end portion <NUM>(<NUM>) to conduct current through the biasing element <NUM> and to wire W from windings <NUM>.

The rear suspension <NUM> is in the form of a resiliently flexible nipple <NUM> (e.g., formed of a silicone material) having one end <NUM>(<NUM>) provided to the cap <NUM> of the core housing <NUM> and an opposite end <NUM>(<NUM>) provided to the main body <NUM> of the housing <NUM>.

In the illustrated embodiment, the end <NUM>(<NUM>) includes an annular recess <NUM> adapted to receive the edge of an opening <NUM> provided in the lower wall of the main body <NUM>.

In use, the resiliently flexible nipple <NUM> support the rear portion of the core <NUM> within the housing <NUM> while isolating the core <NUM> from the housing <NUM>, e.g., vibration isolated.

Claim 1:
A PAP device (<NUM>) for generating a supply of pressurized gas to be provided to a patient for treatment, the PAP device (<NUM>) comprising:
a housing (<NUM>);
a core (<NUM>) including a motor (<NUM>) and at least one impeller (<NUM>); and
a vibration isolation system (<NUM>) to support the core (<NUM>) within the housing (<NUM>) in a flexible, vibration-isolated manner,
wherein the vibration isolation system (<NUM>) includes a front suspension (<NUM>) to support a front portion of the core (<NUM>) and a rear suspension (<NUM>) to support a rear portion of the core (<NUM>);
wherein the front suspension (<NUM>) includes a plurality of biasing elements (<NUM>); and
wherein one or more of the biasing elements (<NUM>) are coupled to windings (<NUM>) of a stator assembly (<NUM>) to conduct current from an external source to the windings (<NUM>).