This application claims the benefit of German Application No. 102004052054.2 filed Oct. 26, 2004, German Application No. 102004053324.5 filed Nov. 4, 2004, and German Application No. 102005000819.4, filed Jan. 5, 2005, each incorporated herein by reference in its entirety.
The invention relates to an apparatus for administering a breathable gas, in particular room air, at a pressure level that is at least in some phases above the ambient pressure. The invention also relates to components of such an apparatus. In particular, the invention is directed to a device, in particular a Continuous Positive Airway Pressure (CPAP) device, for treatment and/or diagnosis of sleep-related breathing problems by bringing about a pneumatic splinting effect in the region of the upper airways.
In CPAP devices, the breathing gas delivered to a user is typically pumped by a pumping device to a pressure level that is above the ambient pressure. This pumping device can in particular be embodied as a blower, with a motor-driven impeller in the form of an axial, semiaxial, or radial impeller. The pumping device per se forms a pressure lock, by means of which a portion of an air guidance system toward the patient is at a higher pressure than an intake-side portion of the air guidance system that is open to the environment. Conducting the breathing gas on from this pumping device to a user can be done via a flexible hose and a breathing mask device connected to it. Typically a patient uses these devices at home, where they can be placed in the immediate vicinity of the patient's pillow, for instance on a night table.
Thus to attain the greatest possible treatment comfort, CPAP devices are typically embodied such that they cause the least possible operating noise. To reduce the operating noise, it is possible in particular to provide sound-absorbing air guidance structures in the interior of the CPAP device, for absorbing any acoustic events that are coupled into the breathing gas path by the pumping device. These air guidance structures may in particular be lined with a sound-absorbing material. These sound-absorbing materials are typically foam material or material that otherwise has pores, such as foam. Cleaning this air guide proves relatively problematic.
One such apparatus is known particularly from the present Applicants' International Patent Application WO 01/10489 incorporated herein by reference in its entirety. This apparatus includes a basic unit and an air humidifier device that can be coupled in modular fashion to it. The basic unit in turn includes a housing device and a blower device located in the housing device. The blower device is incorporated into a breathing gas path, which on both the suction side and the pressure side is embodied as a labyrinth structure, for absorbing any running noises that the blower device may have.
Depending on the configuration of a CPAP device, a patient's exhaled breathing gases may get back into the CPAP device. The level of patient's exhaled breathing gases getting back into the CPAP device is influenced by factors such as the length of the breathing gas hose; the breathing gas rinsing flow toward the mask; and the patient's inhalation volume. Cleaning these CPAP devices is typically performed by skilled persons skilled in the equipment and furthermore proves to be relatively time-consuming.
To overcome the problem of cleaning the air path, disposable or sterilisable air paths were designed. German patent DE 2941554 discloses a sterilisable air cartridge that can be used in medical devices such as ultrasound atomizers. Wickham et al have three US patents (U.S. Pat. Nos. 6,302,105; 6,629,528; and 6,899,100, each incorporated by reference in its entirety) relating to a sterilisable or disposable air path. However, these devices are not designed to allow inexpensive manufacture of a range of devices that deliver a range of different therapy modes.
One aspect of the invention is to create an apparatus of the type defined at the outset that is distinguished by highly convenient manipulation and also proves advantageous from the standpoint of manufacture, assembly, and maintenance, including hygienic and noise aspects.
One embodiment of the invention relates to an apparatus for administering a breathable gas, in particular at a pressure level that at least in some phases is above the ambient pressure, having a delivery device for delivering the breathing gas via a breathing gas delivery path, a breathing gas inlet region, located upstream of the delivery and forming part of the breathing gas delivery path, and an outlet region, downstream of the delivery device and likewise forming part of the breathing gas delivery path. The breathing gas inlet region and the breathing gas outlet region are furnished by a first module having at least one sound-absorbing structure.
Another embodiment of the invention relates to an apparatus for administering a breathable gas, in particular at a pressure level that at least in some phases is above the ambient pressure, having a delivery device for delivering the breathing gas via a breathing gas delivery path, a breathing gas inlet region, located upstream of the delivery device and forming part of the breathing gas delivery path, an outlet region, downstream of the delivery device and likewise forming part of the breathing gas delivery path, and a housing structure. The apparatus in its construction is broken down into a first module and a second module, and the first module includes the delivery-path components that serve to furnish the breathing gas delivery path, and the second module includes the apparatus components that can be separated from the delivery path components.
Yet another embodiment of the invention relates to a device for delivering a breathing gas, having a air delivery device for pumping the breathing gas to a pressure level that is above the ambient pressure, and having a basic unit for receiving the air delivery device, in which the air delivery device forms part of a first module, and the basic unit forms a second module, which is divided up into a lower structural part and an upper structural part, and the two structural parts can be put into an open position toward one another, and in this open position the first module can be removed from or introduced into the second module.
Aspects of the invention may make it possible to break the equipment down into one group that requires regular maintenance or cleaning and a second group that requires less cleaning and maintenance. Aspects of the invention make it possible to replace the structures that enter into communication with the breathing gas in a replacement operation, for example, in a way similar to how a toner cartridge is handled for a laser printer, whilst the electronic components may continue to be used. Furthermore, embodiments of the invention make it possible to construct various equipment configurations inexpensively using modules that are compatible both geometrically and in terms of circuitry.
The first module preferably includes the breathing gas line portion that defines the breathing gas inlet region; this breathing gas line portion that defines the breathing gas inlet region is preferably provided with a sound damping unit.
The first module preferably includes a breathing gas line portion that defines the breathing gas outlet region. This breathing gas line portion that defines the breathing gas outlet region is likewise preferably provided with a sound damping unit.
According to a preferred embodiment of the invention, the first module includes a first module housing, which is embodied as a thin-walled structure. This thin-walled structure may be made from a plastic material or preferably from a foil- or film-coated cardboard material. The first module housing receives the sound damping units and the delivery device and may be a disposable item. It is possible to design the first module in terms of its construction such that the first module or the first module housing is reinforced by structures enclosed in the first module housing, in particular the aforementioned sound-absorbing structures. This makes it possible to prevent swelling of the first module housing in response to the breathing gas pressure that may prevail downstream of the delivery device.
In an especially preferred embodiment of the invention, the first module housing is designed to include defined breathing gas duct portions, in particular an intake portion and an outlet portion. These breathing gas duct portions may be exposable by removing cover portions. These cover portions may be formed directly by the wall material of the first module. The cover portions to be removed may be defined by perforated places in the first module housing.
In the first module housing, it is possible to provide a connection portion for connecting the delivery device. The delivery device may either be attached to the first module or, in an especially preferred embodiment, be inserted at least partway into the first module. Particularly in the latter case, the delivery device may be received in a receiving portion in the first module. This receiving portion may be embodied as a recess, for receiving an insert that includes the delivery device.
It is possible to design the first module such that the delivery device is initially integrated with the first module and upon replacement of the first module is removable from the first module. The removal of the delivery device from the first module is preferably accomplished with relatively simple disassembly and preferably largely without tools. As a result, it becomes possible to process the delivery device for a further use.
The first module is preferably designed such that measuring instruments, or structures such as tubular stubs intended for forming breathing gas line portions can be coupled to it. The docking may be accomplished in conjunction with fasteners that are already fixed in advance to the first module housing.
The delivery device is preferably embodied as a blower. The blower device includes a motor having an impeller coupled thereto. The impeller is preferably a radial wheel with backward-curved vanes. It is possible to embody the blower device as a disposable component. However, it is also possible to construct the blower device in parts in such a way that the components that are relevant to sterilization and cleaning can be disconnected from the actual impeller drive device. The kinematic coupling of the impeller device to the drive device can be accomplished in particular by means of a magnet coupling. However, it is also possible to embody the impeller such that it functions as part of the motor, in particular as the motor rotor, for instance a short-circuit rotor.
The first module may be constructed so that it is subdivided into a plurality of component elements. For instance, it is possible for the portion of the breathing gas delivery path on the intake side and the portion of the breathing gas delivery path on the compression side to be embodied as separate disposable modules. The delivery device for delivering the breathing gas may also be integrated with a basic unit provided for receiving the first module.
The sound damping unit provided in the region of the breathing gas inlet region is preferably integrated, as a replaceable inlet sound damper unit, with the first module. The sound damping unit provided in the region of the breathing gas outlet region is preferably also integrated, as a replaceable outlet sound damper unit, with the first module. It is possible to combine the two sound damper units into an interchangeable unit, which can be changed in the course of a maintenance or sterilization operation.
Furthermore, the first module preferably includes a transducer, for picking up a measurement signal that is indicative of the flow of breathing gas. This transducer may be embodied as a differential pressure transducer. The differential pressure required for raising this measurement signal can be built up intrinsically via the breathing gas path. It is also possible to embed structures suitable for building up a differential pressure in the breathing gas path. It is also possible in the region of the breathing gas path to provide other kinds of sensor structures, by way of which a signal indicative of the breathing gas flow can be raised.
Preferably, by means of the first module housing, connection devices are furnished for coupling further elements of the region of the breathing gas delivery path located downstream of the delivery device, in particular for direct coupling of a breathing gas hose. The connection devices of the first module are preferably embodied and disposed such that they are accessible via a connection portion that is bounded by the second module.
It is advantageously possible to embody the first module and the second module as components substantially stacked one above the other. The second module may in particular be embodied such that it includes an upper housing device; the equipment operating devices and in particular the equipment electronics are integrated with the second module.
The second module preferably also includes a mains voltage connection structure. The mains voltage connection structure may furthermore be provided with a mains switch, provided for manual actuation, and this mains switch is disposed in the immediate vicinity of the mains voltage connection structure or of where a power cord enters the second module. The connection of the power cord to the second module can be made via an outlet, and the mains switch may be combined with the outlet to make a structural unit. The second module may also be coupled with a power pack.
In a preferred embodiment of the invention, the second module includes a lower structural part intended for receiving the first module and an upper structural part covering this lower structural part, forming an upper equipment face.
In a further preferred embodiment of the invention, the upper structural part is pivotably coupled to the lower structural part. This type of coupling can be attained in particular using pivot pins or pivot guide portions, which are embodied correspondingly complementary to the two structural parts.
In an especially preferred embodiment of the invention, both the upper structural part and the lower structural part each form one housing half-shell. These housing half-shells are preferably embodied such that after the upper structural part has pivoted upward, the first module can be inserted from above into the lower structural part. It is possible to embody the coupling of the two structural parts, in particular the joint structure serving the purpose of the pivotable coupling, such that the structural parts are separable from one another in a defined pivoted position, so that in particular the upper structural part can be removed from the lower structural part.
It is also possible to embody the joint structure, preferably intended for coupling the two structural parts, such that the pivot axis defined by the joint structure extends in the region of the front or optionally also rear crosswise edge of the basic unit. If the joint structure is embodied such that this pivot axis extends in the region of the front crosswise edge of the basic unit, then it becomes possible to lift the upper structural part in the rear portion of the basic unit and pivot it forward. In this pivoted state of the basic unit, the first module can be inserted into the lower structural part from behind, without requiring that the upper structural part be removed completely from the lower structural part for the purpose.
In an especially preferred embodiment of the invention, a control circuit and a voltage supply circuit are detachably disposed in the region of the upper structural part. This control circuit and the voltage supply circuit are preferably divided into separate electrical modules. In particular, it is possible to embody these electrical modules such that certain user-control-relevant portions of these modules are open to the environment through recesses or openings embodied in the upper structural part and are thus accessible to a user. Moreover, it becomes possible to embody the electrical modules such that voltage supply circuits or switches provided in them are also freely accessible at the rear of the device. It is also possible to embody the electrical modules such that any air throughput opening portions required for cooling the electrical components of these modules are freely accessible in the rear region of the device of the invention and/or toward the top of the device.
The basic unit formed by the first and second modules is preferably designed such that the equipment furnishes a connection device for selective connection of an air humidifier. In the region of this connection device the basic unit may be designed such that after docking of an air humidifier, the result is a largely closed structure. A covering element may be provided to cover the region surrounding the connection device when the equipment is used in a configuration without an air humidifier attached, thus maintaining an attractive external appearance of the basic unit in either configuration with or without the air humidifier.
In a preferred embodiment of the invention, line portions are furnished in the region of the upper structural part, for creating an electrical connection between the electrical modules, inserted into the upper structural part, and optionally to the first module and/or also to the air humidifier device. This line system (or common rail system) can be embodied such that the corresponding electrical docking of the electrical modules, of the first module, and/or of the air humidifier device is achieved when these modules are inserted properly into the upper structural part. Alternatively, or in combination with this provision, it is also possible to embody the aforementioned electrical modules such that any required electrical connections between these modules are attained when these electrical modules are disposed suitably side by side in the upper structural part or are placed onto the first module. It is possible for the modules to be embodied such that control-relevant signals are communicated in wireless fashion, in particular optically or in some other way electromagnetically or field-electrically. For instance, it is possible to perform a voltage supply for a heater of the air humidifier via the power pack, and the power pack has a signal input interface for receiving a signal intended for triggering a power switch. This signal can be furnished via the control module.
The air humidifier preferably includes a cup portion and a cap element closing off the cup portion. The cap element preferably defines an air supply path, for creating a connecting path between the outlet portion of the first module and the inner region of the cup portion. The cap element may be embodied such that it includes a connection stub for connecting a breathing gas line. This connection stub is preferably embodied integrally with the cap element.
In a particularly preferred embodiment of the invention, the air humidifier is provided with an electric heater. The heater may be formed by a heating bar. The heating bar is preferably incorporated detachably into the air humidifier. It is possible to incorporate the heating bar into the air humidifier of the cap element, in particular by providing that the heating bar is detachably coupled with the cap element.
It is possible to embody the air humidifier such that the heating bar is guided all the way through the cap element in a sealing manner. The heating bar may be detachably locked to the cap element, and may be provided directly with an electrical connection device embodied on an end portion of the heating bar. The electrical connection device may be embodied such that in the course of coupling the air humidifier to the basic unit, it likewise couples with corresponding electrical connection elements of the basic unit.
The cap device preferably includes a partition element, for separating an airway extending in the cap element, from some portions of the inner region of the cup portion. This partition element is preferably removable, so that the airway extending in the cap element is advantageously freely accessible for cleaning purposes. The partition element may be made from an elastomer material and may at the same time perform sealing tasks for sealing off the cup portion and/or the heating bar element.
It is possible to provide a storage device, for instance in the form of a memory chip, in a component associated with a blower device, in particular in a motor plug, by way of which blower device or chip hygiene-relevant information or operation-relevant information and data can be recorded.
It is possible to equip the hygiene-relevant components with a display, such as thermal paper labels, that make it possible to ascertain whether or to what extent the applicable component has already been used up. The change in color of the thermal paper label can be brought about using small heating resistors located in the vicinity of the display. Via such a display, it is also possible to implement a display of hours in operation.
It is also possible to detect other kinds of hygiene-relevant events and to record information accordingly. For instance, the hygienic condition can be ascertained as a function of the rebreathing volume. The corresponding information may be obtained from a breath flow signal that is raised, for instance, via a differential pressure sensor.
As a result, it advantageously becomes possible to create a breathing gas delivery device, in particular a CPAP device, in which an air feeding module that is relevant to hygiene can be removed from or inserted into the applicable receiving system in a way similar to how a toner cartridge is handled for a laser printer.
One device of the invention is preferably embodied such that the hygiene-relevant first module is replaceably insertable into the lower structural part. The electrical modules required for performing the control operations as well as the voltage supply are preferably detachably inserted into the upper structural part. The concluding electrical and mechanical coupling of these modules is preferably done whenever the upper structural part, equipped with the electrical modules, is pivoted over or otherwise moved onto the lower structural part. It is possible to embody the electrical modules such that an intrinsically functional breathing gas supply device can be constructed by simply placing these electrical modules against the first module, and in that case the hinged housing system can initially be dispensed with. In an alternative embodiment, it becomes possible to construct an abbreviated system suitable for a patient from the hygiene-relevant first module and the electrical modules and to perform an examination of the patient initially only with this abbreviated configuration. If a need for therapy for the examined patient is found, then the system used for the examination can be supplemented with the upper and lower structural parts of the second module and thus assembled into a therapy device that is both aesthetically attractive and suitable for use at home.
The two structural parts are preferably made from a plastic material. The electrical modules are preferably embodied such that different device variants can be made by suitable selection and combination of various compatible individual modules. The control circuit, or the module carrying this control circuit, may be part of a module family that furnishes control circuits by which modules are furnished that differ in terms of the complexity of control or in terms of the required control characteristics. It is also possible to embody the control circuit or the control module such that the appropriate configuration of this module in terms of regulation can be software-based, in particular by inserting a memory card element that specifies the pressure regulating concept.
Further details and characteristics of the invention will become apparent from the ensuing description in conjunction with the drawings.
a is a perspective view of the equipment in
b is a perspective view of a structural part of the second module of the apparatus of
c is a perspective view of the structural part of
a is a perspective view of the first module according to a preferred embodiment of the invention;
b is a perspective view of the first module in the receiving portion of the second module;
a and 37b are each sketches for illustrating the construction of an insert element for the inlet portion on the suction side of the first module;
a is a simplified side view of a device according to an embodiment of the invention, having a hinged second module that includes a lower structural part and an upper structural part;
b is a side view illustrating an open position of the second module of
c is a sketch illustrating a modularly dockable air humidifier;
a is a sketch illustrating opening portions, embodied in the upper structural part, for making user-control areas of an electrical module accessible;
b is a sketch illustrating a flip display, which forms part of the control module and which can be viewed above the top of the upper structural part at various erected positions;
a is a sketch illustrating one possible design of a joint structure intended for coupling the two structural parts, which makes both pivotable coupling and the removal of the upper structural part from the lower structural part possible;
The first module housing 2 is embodied as a thin-walled structure. This thin-walled structure may in particular be formed of a foil- or film-coated cardboard material, such as the material also known as Tetra-Pak material. The first module housing 2 may be reinforced by the structures received in the first module 1, in particular sound-absorbing structures, so that the first module housing 2 has adequate strength, particularly overpressure strength. The first module housing 2 in this exemplary embodiment is provided with a plurality of perforated plates 3, 4, 5. Via these perforated plates 3, 4, 5, immediately before the first module 1 is used, the opening portions required for operation of a CPAP device can be exposed in the first module housing 2. Via the perforated plate 3, for instance, a wall portion 6 of the first module housing 2 can be torn off, so that a recessed portion 7 intended for receiving a delivery device 16 is exposed.
It is also possible to configure the first module 1 such that it initially has a delivery device 16 (
Via the perforated plate 4, in this exemplary embodiment, an opening portion can be exposed in a side region of the first module 1, and breathing gas is delivered via this portion. In the region of this opening portion, as shown in
Via the perforated plate 5, a compression-side outlet line region of the first module 1 can be exposed. By furnishing the first module 1 as an initially hermetically sealed unit, it becomes possible to prevent any contaminants from getting into the interior of the first module 1. Moreover, when the perforated plates 3, 4, 5 are intact, it is immediately apparent that the first module 1 itself is new and has not yet been used.
Breathing gas conduits adapted to the structural form of the delivery device 16 and to the position of the incoming and outgoing portions of the breathing gas delivery path may be embodied in the first module 1.
When the first module housing 2 is made of cardboard material, it becomes possible to create folding or crimping zones 13, such that they do not cause any irritating raised areas on the outer surface of the first module 1. It is possible to provide recesses in the foam insert elements 10, 11, so that any folding or crimping protrusions can fit into them.
As an alternative to connecting the power supply to the delivery device 16 through the flexible line portion 14 shown here, it is also possible to provide plug structures on the first module 1, in particular socket portions 15 shown in suggested form here, which can be brought into engagement with complementary counterpart plug portions provided on a second module 21. Other kinds of contact concepts may also be utilized to create a disconnectable electrical connection between the first module 1 and a second module 21 (
In
The conduit portion 18, for instance, forms a compression-side portion of the breathing gas delivery path 20 and communicates with a stub portion 19, shown in suggested form here, to which an air humidifier 39 (
In
The line stub 31 may be embodied in one piece with other functional components of the air humidifier 39, or it may be embodied as a plug-in stub, to which the other airway portions of the air humidifier 39 can be connected. In the exemplary embodiment shown here, the line stub 31 is embodied integrally with a cap portion 33 of the air humidifier 39. A cup element 34 for receiving humidifying water is placed in a sealing fashion against this cap portion 33. The cup element 34 is dimensioned to have a bottom spacing from a surface on which the equipment stands on, making it possible to remove the cup element 34 from the cap portion 33 from below without lifting the CPAP device.
The air humidifier 39 shown here includes a heating bar element 35, which is coupled in sealing fashion to the cap portion 33. The heating bar element 35 is embodied such that it can be disconnected from the cap portion 33 in a simple way, without tools. The plastic parts shown here, that is, the cup element 34, the cap portion 33, and preferably the line stub 31 that is integral with the cap portion 33, may be embodied as disposable components, which can be replaced or disposed of after a certain length of time in use, or after use by a single patient. The heating bar element 35 is preferably embodied such that it can be used multiple times. The heating bar element 35 is inserted, for instance via an elastomer stopper 36, through the cap portion 33 into the cup element 34 in a sealing manner.
In
Using the receiving structure 40 and the connection plate 41a pressure measurement conduit system may be defined to obtain a differential pressure signal indicative of the breathing gas flow. This pressure measurement conduit system may have pressure measurement line portions 44, 45 and 44′, 45′, respectively, which in the joined position of the connection plate 41 communicate with pressure measurement conduits 46, 47 and 46′, 47′, respectively. The pressure measurement conduits 46, 47 are extended in the interior of the first module 1 in such a way to allow measurement of a differential pressure signal, which is in a largely linear relationship with the flow of breathing gas, within the breathing gas delivery path.
The pressure measurement conduit stubs 44, 45 may be located such that when the line stub 31 is attached or the connection plate 41 is inserted, they enter directly into engagement with corresponding pressure pickup conduit portions of the first module 1.
In
In
In
In the abovementioned exemplary embodiments, all the hygiene-relevant components of the breathing gas are integrated into a single first module. However, the invention is not limited to this principle. For instance, it is also possible to provide separate (replaceable) delivery path elements for both the intake region of the breathing gas delivery path and the compression region of the breathing gas delivery path (see below for further detail). The delivery device 16 can be embodied in parts such that its electrical components can be disconnected from the components that come into contact with the breathing gas.
The detection of a signal indicative of the breathing gas flow can be made in the form of a differential pressure detection. As an alternative, other kinds of physical interaction effects may be used for generating a corresponding signal. For instance, it is possible to provide an element in the region of the breathing gas delivery path 20 that deforms or bends as a function of the speed of the air flowing past, and for the deformation to be detected optically. For instance, it is possible to provide a flexible waveguide in the region of the breathing gas delivery path 20 that emits a beam of light whose orientation varies as a function of the instantaneous breathing gas flow.
In a first embodiment the first module 1 of the invention may be used in the flowing manner to make a completely sterile CPAP device. Initially a first module 1 of the invention is picked up and prepared suitably for assembly, by detaching one wall portion 4 of the first module 1 that covers an inlet region and one wall portion 5 that covers a breathing gas outlet line region from the first module 1 at perforated places provided for the purpose. The thus-prepared first module is inserted into a receiving portion of a second module 21. In the second module 21, electrical contact elements enter into engagement with contact portions that are embodied in the region of the first module 1. As a result, a current circuit is formed that extends via a blower motor. An air humidifier is now attached to the first module 1 that has now been inserted into the second module 21. Attaching the air humidifier 39 is done by pushing a connection plate 41 of the air humidifier 39 against a receiving structure 40, provided for instance on the first module 1. Docking of the air humidifier 39, or of the breathing gas line portions that lead to the air humidifier 39, makes it possible to couple a differential pressure sensor, provided in the region of the connection plate 41, to pressure pickup points that are provided in the region of the receiving structure 40 preferably provided on the first module 1.
A breathing gas hose may be connected to the air humidifier 39, and a breathing mask can be connected to this hose in a known manner. To this extent, a ready-to-use system for delivering a breathing gas is now attained.
If after this system has been used a need for cleaning arises, the breathing gas hose and the breathing mask may be disconnected from the air humidifier 39 and cleaned, each as separate parts, with a preferably heated cleaning solution, and optionally heat-treated afterward.
The air humidifier 39, and the first module 1 of the invention, may be disconnected from the second module 21 and either cleaned or disposed of. After the first module 1 is removed from the second module 21 the delivery device 16 received in the first module 1 may be removed from the first module 1. The delivery device 16 and optionally the air humidifier 39 may be taken to a system processor and optionally delivered for a further use. The other components of the first module 1 may be disposed of.
An electrical outlet device 112 for connecting a power cord and a mains switch 113 are provided on the second module 104. The mains switch 113 and the outlet 112 can be combined into a subsidiary group (mains structural unit). The electrical outlet device 112 is embodied and dispensed such that any contaminants penetrating it, or water penetrating it, can advantageously fall out or flow out of this electrical outlet device 112. The electrical outlet device 112 and the mains switch 113 are integrated into an upper structural part 114 of the second module 104. As a result, the electrical connection between the electrical components coupled to the upper structural part 114 can be maintained even after the upper structural part 114 has been detached from a lower housing part 115 of the second module 104.
The lower housing part 115 is a structural part that forms a receiving portion for receiving the first module 103 shown in
The air humidifier 102 is coupled to the basic unit 101 using a cap element 116, which is pivotably and detachably connected to the upper structural part 114 of the basic unit 101 via a hinge device (not shown). Flipping the cap element 116 open makes it possible to remove the actual components of the air humidifier 102 from the basic unit 101. In this embodiment, however, the cap element 116 not only serves as a cladding element but also serves to lock the actual air humidifier 102 to the basic unit 101.
a shows the basic unit 101 of the equipment of
b shows the lower housing part 115 of the second module 104. This lower housing part 115 is provided with a handle 119, which serves to make it easier to manipulate the basic unit 101. The handle 119 forms a grip crosspiece, which at lateral fastening portions 120, 121 merges with the main structure of the lower housing part 115. The fastening portions 120, 121 are curved in such a way that by means of the handle 119, a support structure is furnished on which a portion of a breathing gas hose can be placed (not shown).
The lower housing part 115 forms three main receiving portions, accessible from below, for receiving the first module shown in
c indicates the positions of the connection stub 117 and the measurement stub structure 134 when the first module 103 is inserted into the receiving chamber of the lower housing part 115 shown in
In
The main cap 141 of the air humidifier 102 forms a fastening structure 144 for fixation of a heating bar 145. In this embodiment, the heating bar 145 is bent over and is coupled detachably to the main cap 141 of the air humidifier 102 via the fastening structure 144. The heating bar 145 is extended in sealing fashion through the main cap 141 of the air humidifier 102. The sealing is accomplished by a duct element 146, which is made of an elastomer material and which, as will be described in further detail hereinafter, forms an integral component of a partition element 150 (see
The heating bar 145 is provided with an electrical connection element 147, which upon docking of the air humidifier 102 to the basic unit 101 shown in
The angle stub 148 is fundamentally not a component of the air humidifier 102 but connects the air flow from the basic unit 101 to the air humidifier 102. The angle stub 148 is placed on the connection stub 117 of the first module 103 (see
The opening 153 embodied in the main cap 141 of the air humidifier 102 serves as a passage for the heating bar 145, as shown in
The breathing gas line portion 143 of the main cap 141 of the air humidifier 102 predominantly forms a channel, which is open toward the underside of the main cap 141 of the air humidifier 102 and is thus easy to clean. As can be seen from
In
A covering structure 136 may also be coupled to the first module 103, and through it the breathing gas inlet region, not visible here in detail but furnished through an opening in the component 130, can be covered. A filter device, in particular a filter made from a foamed plastic material, can be replaceably disposed in the region of the covering structure 136.
The first module 103 includes the three main portions 131, 132 and 133 as mentioned above. These main portions each preferably have a cubic construction. The connection stub 117 is seated on the outlet portion 133 and is oriented such that in the position for use it extends substantially vertically. The measurement stub structure 134 is also embodied such that it rises, essentially parallel to the center axis of the connection stub 117, from the outlet portion 133.
In
The delivery device 160 is received in a housing 160a, which is preferably made from a material with a relatively high specific weight, in particular metal. The housing 160a in this exemplary embodiment is braced via an elastomer structure 162 in the delivery device receiving portion 132. The elastomer structure 162, as will become clear below in conjunction with
The first module 103 is constructed to minimize the number of deflection points created in the breathing gas path. As a result, the flow resistance of the breathing gas path is reduced considerably, compared to conventional constructions. The course of the breathing gas path is approximated here by the dot-dashed line LI. As already noted, in the inlet portion 131 and outlet portion 133, there are preferably foam insert elements 190 (see
In
In
The blower 165, as shown in
The pressures picked up via the two differential pressure measuring conduits 171, 173 can advantageously be applied, via the measurement stub structure 134 shown in
In
a and 37b show an insert element 190 in simplified form. The insert element 190 is made from a foamed material and defines a breathing gas path portion 191. The breathing gas path portion 191 has a course curved only once, for the sake of attaining a slight flow resistance. In this respect, a departure from the previously conventional labyrinth attachments is made. On the inlet side, a stub element 161 protrudes into the breathing gas path portion 191, and this stub element 161 forms an acoustic trap in cooperation with the chamber wall that receives the insert element 190.
In
The constructed characteristics described above, particularly the details described in conjunction with
The device shown in
The air humidifier shown in
In
It is possible for these two modules A, B to be embodied such that they can be coupled electrically directly to one another in the way required. It is also possible, in the region of the upper structural part 202, to provide a common rail electrical rail C, by way of which a suitable electrical coupling of the electrical components received in the device of the invention can be attained. This electric rail C is embodied in this exemplary embodiment such that the electrical modules A, B can be docked to it. This rail system C also furnishes contacts 215, 216, by way of which an electrical connection with the first module, not visible in this view, is attainable as soon as the upper structural part 202 has been pivoted into the closing position.
In
The recessed portion AS may be embodied such that, as sketched in
The first module, intended for insertion into the basic unit embodied according to the invention, is shown as an example in
The first module 203 forms a compression-side connection portion AB, which in this exemplary embodiment is embodied such that a stub portion, embodied on the bridge element of an air humidifier (for which see
Guide structures 225, 226 are embodied on the first module 203, which facilitate the positionally correct insertion and fixation of the first module 203 in the lower structural part 201 (see
The device of the invention is preferably dimensioned such that its base has dimensions in the range of approximately 20×20 cm. The height of the device is preferably in the range of approximately 11 cm. The air humidifier module may protrude past the aforementioned base, in particular toward the front.
In
By the modular concept of the invention, it becomes possible to create a CPAP device which can be broken down into its main components without tools, optionally even by the user himself. Because it is easy to break down, the hygiene-relevant device components, and in particular the first module 203, can be replaced easily. It moreover becomes possible, from the individual compatible modules, to create a device adapted individually to the requirements of the user. The upper structural part 202, as the structural part that predominantly determines the overall appearance of the device of the invention, can be chosen to suit a patient's wishes in terms of color. Preferably, except for the electrical devices of the first module, all the other electrical components are located in the region of the upper structural part 202, or of the individual modules received in it.
The air humidifier device may also be embodied in a different way from the variants described above. In particular, it is possible to embody the air humidifier device such that it is not slipped onto the upper structural part 202 from above but instead can be slid from the front into the upper structural part 202.
It is also possible to embody the basic unit such that the first module is insertable into the interior of the basic unit through an insert opening provided in the rear region of the basic unit or in its side region. In general, the first module can be accommodated in insert-like fashion, replaceably, in a modular structure that is easy to open.
While the invention has been described in connection with what are presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Also, the various embodiments described above may be implemented in conjunction with other embodiments, e.g., aspects of one embodiment may be combined with aspects of another embodiment to realize yet other embodiments. In addition, while the invention has particular application to patients who suffer from OSA, it is to be appreciated that patients who suffer from other illnesses (e.g., congestive heart failure, diabetes, morbid obesity, stroke, barriatric surgery, etc.) can derive benefit from the above teachings. Moreover, the above teachings have applicability with patients and non-patients alike in non-medical applications.
Number | Date | Country | Kind |
---|---|---|---|
102004052054.2 | Oct 2004 | DE | national |
102004053324.5 | Nov 2004 | DE | national |
102005000819.4 | Jan 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP05/11467 | 10/26/2005 | WO | 5/23/2007 |