DE29707911U1 - Oxygen supply system - Google Patents

Description

Patent attorneys

GEYER, FEHNERS ^ACTNEl^(£.;ß.R/·;'":

European Patent&KeTnefc I II * *". I

munich-j'ena

Office Munich /Munich Offices: Perhamerstraße 31 · D-80687 Munich Telephone: (089) 5461520 · Fax: (089) 5460392 · Telex: 5218915 gefe d ■ Telegrams: gefepat muenchen

Office Jena//ena Offices: Sellierstraße 1 ■ D-07745 Jena · Telephone: (03641) 29150 · Fax: (03641) 2915

o.Z.: GM 9034/1-97 Jena, 29 April 1997

Medical and health store

Beiger GmbH

Arminiusstrasse 1

07548 Gera

Oxygen supply system

Patent attorneys

GEYER, FEHNERS f?PARTNERj(C.15.Rf _: ";:

European Patents: II * "Il
MUNICH*-JEN*A

Munich Offices: Perhamerstraße 31 · D-80687 Munich
Telephone: (089) 5461520 -Fax: (089) 5460392 -Telex: 5218915 gefe d ■ Telegrams: gefepat muenchen Office )ena//ena Offices: Sellierstrasse 1 ■ D-07745 Jena ■ Telephone: (03641) 291 50 · Fax: (03641) 291521

Beiger GmbH Jena, 29 April 1997

o.Z.: GM 9034/1-97

"Oxygen supply system"

The invention relates to an oxygen supply system for human medical oxygen therapy with a generation and output system for a breathing gas highly enriched with oxygen, with an inhalation apparatus for the patient and with a connecting line for supplying the breathing gas from the generation and output system to the inhalation apparatus, wherein the generation and output system is accommodated in a housing.

In human medicine, oxygen is administered to patients in many cases of illness and often after operations. Depending on the duration of such administration, a distinction is made between short-term and long-term applications. Due to the increase in civilization- and environment-related diseases, there is an increase in long-term applications in particular and this is certainly expected to continue in the future. An additional reason for the increase in long-term applications is the increase in the average age of the population and the increased awareness of health.

Long-term use of oxygen therapy is increasingly being carried out as home treatment, whereby an oxygen production and oxygen supply system is installed in the patient's home environment, giving the patient the opportunity to inhale oxygen or highly oxygen-enriched breathing gas as needed or as directed. On the one hand, home treatment is supported by health insurance companies, as it avoids hospital stay costs, but on the other hand it also generally meets the patient's wish to carry out the therapy at home.

Beiger GmbH Page &igr;

o.Z.: GM 9034/1-97

GEYER, FEHNERS#P£R*WjJER ]«(?.??)" .·% ····
MONCHfN JJ *

This desire is based on both the need for well-being and the patient's desire to maintain or regain his freedom of movement. The patient's mobility has a significant influence on the rehabilitation process and his quality of life. This explains why new devices that have improved utility properties in this regard are readily accepted by patients, health insurance companies and doctors.

Devices that administer oxygen are well known in medical technology, based on the provision of oxygen in bottles and delivery to the patient via an oxygen tube. A major disadvantage of this technology is that the bottles empty very quickly during use and reserve bottles must be provided after very short periods of time. For example, for long-term patients it may be necessary to provide a newly filled bottle every day, which involves filling and transporting the bottle. Another disadvantage is the fact that oxygen bottles are pressure vessels that represent a source of danger in the home environment and are therefore subject to safety regulations, the disregard of which can have serious consequences. In addition, oxygen bottles are relatively heavy and handling them is problematic for patients who are also physically weak. For these reasons, oxygen bottles are now mainly used for short-term use, e.g. in ambulances for on-site accident treatment.

For long-term applications, so-called oxygen concentrators have become established, in which oxygen or a breathing gas highly enriched with oxygen is produced for immediate use. Modern oxygen concentrators have intelligent oxygen-saving systems in which the oxygen supply to the patient is dosed according to the indication. How much oxygen the patient needs depends on the indication and the patient's physical strain.

The dosage of oxygen supply depends on how the patient, for example, specifies the flow rate using a selection of switch positions. In addition, the patient is only served during the most oxygen-effective phase of his breathing. This takes advantage of the fact that the inhaled oxygen only reaches the lungs for gas exchange at the beginning of each breath, while the remaining oxygen is used solely for dead space ventilation and is exhaled unused. The oxygen-saving systems therefore ensure that the patient is not exposed to oxygen during breathing.

Beiger GmbH Page 2

o.Z.: GM 9034/1-97

GEYER, FEHNER§,4-ty\|*Ty ER.(«e.,b;i*.>'MUNICH;-JEN*A*·;***;

oxygen is not supplied continuously, but only at the beginning of the breathing process, as this is when the oxygen is actually effectively absorbed and processed by the body.

A frequently criticized defect in devices already on the market is the noise they generate, which is particularly disturbing for home use and is caused by the device components used to generate and deliver oxygen.

The invention is based on the object of developing an oxygen supply system of the prescribed type in such a way that the noise development is limited.

According to the invention, the object is achieved in that the housing in which the generation and output system is housed is additionally surrounded by a casing. This invention advantageously ensures that the propagation of noises that emanate from the generation and output system and penetrate through the housing to the outside are effectively held back by the casing surrounding the housing. By making the cavity roughly correspond to the outer contour of the housing, it is ensured that the dimensions of the entire arrangement, which now includes both the housing and the casing, are not significantly changed or increased in comparison to the dimensions of the housing.

In a preferred embodiment of the invention, it is provided that the inner walls of the casing are coated with soundproofing material, whereby the soundproofing material is recessed towards the inside of the suitcase and the recess forms the cavity which, in terms of its size and shape, corresponds approximately to the outer contour of the housing. Coating the inner walls of the casing with soundproofing material advantageously ensures that the emission of the noises generated by the components of the generation and output system inside the housing is retained even more effectively by the surrounding casing.

Another very advantageous embodiment consists in that the inner walls of the casing are coated with sound insulation material, whereby the sound insulation material is recessed towards the interior of the casing and the recess forms the cavity.

The sound insulation material can be applied to the inner walls of the casing in several layers, which can consist of different materials. This advantageous

Belger GmbH Page 3

cc: CM 9034/1-97

GEYER,

This design allows for an economical and therefore preferable manufacturing technology for the casing and also results in a further increase in the efficiency of the sound insulation.

A very preferred embodiment provides that the casing is removable from the housing and the housing is designed as a unit that can be transported independently of the casing. This ensures that the mobility limit for the patient is extended, for example by allowing the housing with the generation and output system contained therein to be removed from the soundproof casing and used independently of this casing in places where the noise is not as disruptive as it is at home.

For example, it is conceivable to surround the housing with the sound-absorbing cover, preferably in the home, so that noise that disturbs sleep is avoided at night and during the day the patient or other people in the vicinity are prevented from being bothered by the noise. On the other hand, the patient can carry the slightly smaller and lighter housing without the cover when he or she is outside of his or her home and the noise is not so disturbing. This can be done, for example, by transporting it in a car, by taking a two-wheeled transport frame specially designed to hold the housing when walking, or by carrying it in a shoulder bag.

It can be advantageously provided that the casing consists of two half-shells in the manner of a case, which are connected to one another via at least one hinge joint and can be opened against one another around the hinge axis. This makes it easy to open the casing and to remove the housing from the casing in an uncomplicated manner.

It is advantageous for the two hinged half shells to be secured against accidental opening by a locking mechanism. This reduces the risk of damage to the oxygen supply system due to careless handling.

In a further advantageous embodiment of the invention, it is provided that the casing is provided with at least one passage for the connecting line and/or for further lines, for example for power cables, which are to be laid from the cavity to the outside of the casing.

Beiger GmbH Page 4

cc: CM 9034/1-97

GEYER, jJ

MÜNC!3EN5-)iNA· : II
·· ·♦»· ·· ···

Preferably, a single feedthrough can be provided, whereby this can be designed close to the dividing line of the two half-shells in the form of a recess made in one of the two half-shells. This ensures that the connecting line for the breathing gas from the housing to the inhalation device, as well as the line for the power supply, for example, are not affected by the casing wall and that these lines do not hinder the removal of the casing from the housing. The recess made in one of the two half-shells ensures in a simple way that the housing can be removed immediately when the two half-shells are unfolded and at the same time the lines led through the casing wall are free, so that the casing can be separated from the housing and also from the lines without any further manual intervention.

In a further embodiment, it can be provided that the connecting line as well as any other lines in the section of the feedthrough are surrounded by a sound-insulating sleeve which, when the casing is closed, prevents the formation of a sound bridge from the cavity to the outside.

Preferably, it can also be provided that the housing which encloses the generation and output system is equipped with an operating and display panel on its outer circumference and the casing has a breakthrough opening corresponding to the position of the operating and display panel, through which the operating and display panel can be reached and/or viewed from the outside.

This ensures that optical and acoustic signals, which indicate a power failure or cable effect, leaks in the system or the patient not taking in oxygen, can be perceived, even if the housing on which the control and display panel is located is surrounded by the sound-absorbing casing. Furthermore, this makes it possible to carry out all the necessary manipulations for setting up or programming the oxygen supply system through the casing wall.

In a further very preferred embodiment, it can be provided that the cover is equipped with rollers on its base, whereby a manual change of location is possible easily and without physical effort for the patient if necessary. These rollers can be arranged in such a way that they support the cover against the floor surface at the installation location or alternatively in such a way that first a

Beiger GmbH Page 5

o.Z.: GM 9034/1-97

GEYER, FEHNERSÄPA«TNERiG!b.»·· ,

·

i i

lifting the cover on one side is necessary so that the rollers come into contact with the floor surface and the cover can be moved in a rolling manner.

Finally, it can be very advantageous for the casing to be designed as a carrying case. This makes it very easy to handle both the casing with the housing contained therein and the casing alone.

The invention will be explained in more detail below using an exemplary embodiment. The accompanying drawings show

Fig.1 a cross section through the oxygen supply system according to the invention
Fig.2 an external view of the same

Fig. 1 shows an oxygen supply system for human medical oxygen therapy, in which a generation and output system for a breathing gas highly enriched with oxygen is housed in a housing 1. The housing 1 is surrounded by a casing 2.

The casing 2 consists of two half-shells 3 and 4 in the manner of a suitcase. The inner walls of the two half-shells 3 and 4 are covered with soundproofing material 5, the soundproofing material 5 is cut out in such a way that the casing 2 has a cavity 6, the outline of which corresponds approximately to the outer contour of the housing 1 and which thus accommodates the housing 1, whereby the housing 1 almost fills the cavity 6.

The two half shells 3, 4 are connected to one another via a hinge joint 7 and can be opened against one another around the hinge axis of this hinge joint 7. When opening, the half shell 3 tilts in direction A around the hinge axis of the hinge joint 7, while the half shell 4 tilts in direction B around the hinge axis of the hinge joint 7. The two half shells 3 and 4 can be secured against unintentional opening around the hinge axis by a locking mechanism 8, such as a suitcase lock.

On its outer circumference, the housing 1 is equipped with a control and display panel 9 for manual setting or programming of the generation and output system as well as for its visual function control, for which various optical displays can be provided. In a position corresponding to the position of the control and display panel 9 on the housing 1, the casing 2 has a breakthrough opening

Beiger GmbH Page 6

o.Z.: GM 9034/1-97

GEYER, FEHNER&Si'PAßtNERjfG5b?R."
MONC(JENi-JiflA* JIJ

10 through the casing wall. Functional settings and function checks can be carried out through the opening 10.

A connecting line for supplying the breathing gas from the generation and output system to the inhalation device, for example an oxygen mask for the patient, and an electrical cable for supplying power to the generation and output system are led out of the housing 1 through an opening 11. The connecting line and the electrical cable are shown together as line 12 in Fig. 2.

To guide the line 12 through the wall of the casing 2, an approximately circular passage 14 is provided in the half-shell 4 near the dividing line 13, where the two half-shells 3 and 4 meet. The line 12 is inserted into this passage 14 from the dividing line 13 into the half-shell 4. To avoid a sound bridge at the point of the passage 14, the line 12 is surrounded in this section by a rubber sleeve 15, which hermetically seals the outer circumference of the line 12 against the passage 14.

Finally, the casing 2 is equipped with four rollers 17 on its base 16. Due to the way in which it is shown, only two of these rollers 17 can be seen in Fig.1 and Fig.2. The rollers 17 support the casing 2 and thus the entire oxygen supply system against the base surface 18.

Also to increase the sound insulation or to prevent noise from penetrating to the outside, rubber sealing lips 19 are arranged between the housing 1 and the inside of the half-shell 3 near the opening 10. These are, for example, glued to the sound insulation material 5 and clamped between the sound insulation material 5 and the housing 1 when the casing 2 is closed, whereby the cavity 6 is hermetically sealed to the outside.

If the oxygen supply system according to the invention is used in the patient's home, excellent noise reduction is ensured due to the additional casing 2 around the housing 1. This ensures that all necessary manual function settings and visual function checks can be carried out through the opening 10 on the control and display panel 9. The handles 20 and the rollers 17 arranged on the casing 2 ensure easy handling when moving the device to a different location.

Beiger GmbH Page 7

o.Z.: GM 9034/1-97

GEYER, FEHNERS.&V«/y?TklER.( ⁱ eb&.?*

Munich:-

If it is necessary to remove the casing 2 from the housing 1, for example if the housing 1 with the integrated generation and output system is to be taken on longer journeys and the smaller dimensions of the housing 1 have priority over sound insulation for reasons of saving space, then all that is required is to open the locking mechanism 8, after which the half-shells 3 and 4 can be opened using the handles 20 around the joint axis of the hinge joint 7 and the housing 1 can be removed from the casing 2.

With these few simple steps, housing 1 including cable 12 is completely separated from casing 2 and can be operated without casing 2.

Beiger GmbH Page 8

o.Z.: GM 9034/1-97

Patent attorneys

GEYER, FEHNERa& _: PA-RTNeR^*.bR:) ^# _: *":

European IJiterJt ^torrife^

I *

Office Munich /Munich Offices: Perhamerstraße 31 · D-80687 Munich Telephone: (089) 5461520 · Fax: (089) 5460392 · Telex: 5218915 gefe d · Telegrams: gefepat muenchen

Office Jena/yena Offices: Seilierstraße 1 · D-07745 Jena · Telephone: (03641) 29150 · Fax: (03641) 291521

Beiger GmbH

o.Z.: GM 9034/1-97

Jena, 29 April 1997

List of reference symbols

3.4

10

11 12

14 15 16

17

18 19 20

Housing Enclosure Half shells Sound insulation material Cavity Hinge joint Locking mechanism Control and display panel Breakthrough opening Opening

Line

parting line

Bushing Rubber sleeve Installation surface Rollers

Floor surface Rubber sealing lips Handles

Claims (11)

Patent attorneys GEYER, FEHNER _: f|H European PSterS: Attorney* &idigr; · * **» ·
·« ·«** ·· ··· ·· · MUNICH-JENA Office Munich /Munich Offices: Perhamerstraße 31 · D-80687 Munich
Telephone: (089) 5 4615 20 · Fax: (089) 5 4603 92 · Telex: 5 218915 gefe d ■ Telegrams: gefepat muenchen Büro iena/jena Offices: Sellierstraße 1 · D-07745 Jena · Telephone: (03641) 29150 · Fax: (03641) 291521 Beiger GmbH Jena, 29 April 1997 cc: CM 9034/1-97 Expectations 1. Oxygen supply system for human medical oxygen therapy with a generation and dispensing system for a breathing gas highly enriched with oxygen, with an inhalation apparatus for the patient and with a connecting line for supplying the breathing gas from the generation and dispensing system to the inhalation apparatus, wherein the generation and dispensing system is accommodated in a housing, characterized in that the housing (1) is additionally surrounded by a casing (2). 2. Oxygen supply system according to claim 1, characterized in that the inner walls of the casing are coated with sound insulation material (5), the sound insulation material (5) being recessed towards the interior of the casing (2) and the recess forming a cavity (6) which, in terms of its size and shape, approximately corresponds to the outer contour of the housing (1). 3. Oxygen supply system according to one of the preceding claims, characterized in that the sound insulation material (5) is applied in several layers made of different materials. 4. Oxygen supply system according to one of the preceding claims, characterized in that the casing (2) is removable from the housing (1) and the housing (1) is designed as a unit that can be transported independently of the casing (2). Beiger GmbH Page 1 o.Z.: GM 9034/1-97 GEYER, FEHNER$*&fAT?£NE$*(q.$X* 5. Oxygen supply system according to claim 4, characterized in that the casing (2) consists of two half-shells (3, 4) in the manner of a suitcase, which are connected to one another via at least one hinge joint (7) and can be opened against one another about the joint axis of the hinge joint (7). 6. Oxygen supply system according to one of the preceding claims, characterized in that the two half-shells (3, 4) can be secured against unintentional opening about the hinge axis by a locking mechanism (8). 7. Oxygen supply system according to one of the preceding claims, characterized in that the casing (2) is provided with at least one passage (14) for the connecting line and/or for further lines, preferably for power cables, from the hollow space (6) to the outside of the casing (2). 8. Oxygen supply system according to one of the preceding claims, characterized in that a single passage (14) near the dividing line (13) of the two half-shells (3, 4) is designed in the form of a recess made in one of the two half-shells. 9. Oxygen supply system according to one of the preceding claims, characterized in that the housing (1), which contains the generation and output system, is equipped with an operating and display panel (9) on its outer circumference and the casing (2) has a breakthrough opening (10) corresponding to the position of the operating and display panel (9), through which the operating and display panel (9) can be reached and/or viewed from the outside. 10. Oxygen supply system according to one of the preceding claims, characterized in that the casing (2) is equipped with rollers (17) on its installation surface (16) to facilitate manual relocation. 11. Oxygen supply system according to one of the preceding claims, characterized in that the casing (2) is designed as a carrying case. Beiger GmbH Page 2 o.Z.: GM 9034/1-97