DE20213232U1 - Respirator, comprising noise absorbing housing for accommodation of turbine provided with inner layer of foam rubber - Google Patents

Abstract

The air is suctioned through a filter (2) into a first chamber, guided into the turbine and released after being compressed into a second chamber. The relation between the position of the outlet at the turbine and the outlet (3) of the second chamber as well as a layer of foam rubber (7) attached to all inner surfaces of the housing (1) results in a remarkable reduction of the noise normally created by the device. The surface of the rubber layer (7) is either plane or ribbed depending on its position in order to increase the noise absorbing effect.

Description

Noise-insulating housing for accommodating a turbine

The invention relates to a housing for accommodating a turbine of a ventilator, which is particularly suitable for emergency ventilation. 5

Measures for noise insulation in turbines are well known.

For example, DE 28 04 653 A1 describes a device for cooling and soundproofing compressors and vacuum pumps that are directly connected to an electric motor that drives them, wherein both the compressor and the drive motor are constructed to be liquid-tight so that they can be arranged in a completely sealed container that contains a cooling and sound-absorbing liquid up to a height at which the compressor or the vacuum pump and the drive motor are completely immersed in the liquid, and whose entire outer surface is provided with a sound-absorbing material.

DE 42 27 543 Cl improves noise reduction in a cleaning device with a suction turbine for generating a suction air flow, with an electric motor driving the turbine and forming a structural unit with the turbine, with a housing accommodating the turbine and with a bracket that secures the turbine and the electric motor to the cleaning device in a sound-insulated manner, in that the bracket is a sleeve made of a thermosetting elastomer with a shore hardness of between 30 and 60, which surrounds the turbine housing and lies flat against the outer wall of the housing at least in some areas, with the turbine being arranged in the cleaning device with the axis of rotation of the turbine running in a vertical direction and the sleeve engaging under the structural unit consisting of the turbine and motor and supporting it freely suspended on the cleaning device.

From DE 199 04 839 A1 a compressor system is known, preferably for stationary use, which has a soundproofing hood in which a self-supporting pressure silencer, a drive motor and a blower stage with associated intake filter are arranged, wherein the soundproofing hood has at least one hinged wall and with a cooling air inlet, a cooling air outlet and a conveying air inlet to the blower stage, to which a

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Intake silencer is connected upstream. According to the invention, a cooling air inlet is arranged at the bottom on the first front wall of the cover opposite the drive motor and a cooling air outlet is arranged at the top on the second front wall opposite the blower stage, with at least one first air guide cassette lined with sound-insulating material and deflecting the air flow several times and provided with at least one air inlet and one air outlet being arranged on the first front wall. The air outlet of the air guide cassette is located opposite the lower cooling air inlet of the first side wall.

These well-known measures do not meet the specific requirements for ventilators.

A housing with a turbine inside is known, which is used in home ventilators for the treatment of sleep apnea syndrome. The turbine with drive motor is arranged in a cuboid-shaped 2-chamber housing, with the first chamber embedded in smooth foam layers.

The air sucked in via an intake port is expelled into the second chamber, redirected several times by means of guide plates with high flow resistance to reduce noise, and exits the second chamber through an outlet port.

The air is guided through a channel via several bends so that there is no direct sound conduction between the turbine and the outlet opening. The disadvantage of this arrangement is a high flow resistance, which limits performance and therefore requires a higher engine power for the same desired air outlet.

This means that the motor and the entire chamber heat up at higher outputs, as may be necessary for emergency ventilation. The resulting heating of the breathing air is undesirable.

Such a turbine housing cannot be used for emergency ventilation, as a significantly higher power reserve is necessary, for example in the treatment of respiratory distress syndrome.

The object of the invention is to create a noise-insulating housing for a turbine that has the power reserve for emergency ventilation. This is achieved

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Task with the features of claim 1, advantageous embodiments are the subject of the subclaims.

The noise-insulating housing according to the invention for accommodating a turbine of a ventilator consists of two completely sealable chambers, whereby both chambers have a foam lining on all chamber walls, the first chamber has an outlet opening for the drive motor of the turbine and the turbine is at least elastically mounted in the outlet opening for the drive motor and in the opening that connects the chambers. The first chamber, in which the turbine is arranged, has an intake port for air and the air compressed by the turbine is discharged into the second chamber, from where it reaches the patient via an outlet port in an air supply hose. In a preferred embodiment, the lining of the second chamber consists of dimpled foam. It is also provided that the lining of the first chamber opposite the intake opening of the turbine is a dimpled foam.

In a further advantageous embodiment, the outlet from the turbine is arranged in the opening between the two chambers and the outlet nozzle from the second chamber exits the chamber offset to the side. Thanks to the insulation using convoluted foam, no air ducts are required, which have a high flow resistance.

By positioning the motor outside the flow chamber, the heat generated during operation can be dissipated independently of the breathing air flow.

An embodiment of the invention is shown in the drawing.

Fig. 1 the opened side view of the housing,
Fig. 2 the opened top view and
Fig. 3 another opened side view.

The housing 1 shown in Fig. 1-3 with intake port 2 and outlet port 3 has two chambers 4, 5, which are connected to each other via the opening 11. Both chambers 4, 5 have a lining 7 made of

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Foam. The lining 7 of the chamber 5 consists entirely of dimpled foam 7.2, while the chamber 4 only has a lining 7 made of dimpled foam 7.2 opposite the intake opening of the turbine 6. Otherwise, a lining made of smooth foam 7.1 is provided here. In a preferred embodiment, the lining 7 of the chamber 5 is designed as an insert, possibly even with its own additional housing, which is then arranged in a soundproof manner opposite the housing walls of the chamber 5.

The turbine 6 is arranged in the chamber 4, wherein the drive motor 10 of the turbine 6 protrudes outward from the housing 1 through an outlet opening 9.

The drive motor 10 and thus the turbine 6 are elastically supported in the outlet opening, preferably with a rubber sleeve 12.

The outlet 14 from the turbine 6 is arranged in the region of the opening 11 connecting the chambers 4, 5 and also elastically supports the turbine 6 here.

The elastic mounting of the turbine 6 in the outlet opening 9 and in the opening 11 prevents the vibrations of the turbine 6 from being transmitted to the housing 1.

The air is sucked into the chamber 4 through the intake manifold and the filter 8, enters the turbine 6 in the middle, is compressed and enters the chamber 5 via the outlet 14 of the turbine 6. The lateral offset between the outlet 14 of the turbine 6 and the outlet manifold 3 of the chamber 5 and the dimpled lining 7 of the chamber 5 achieves a further significant reduction in noise without the performance being impaired by excessive flow resistance.

List of reference symbols Housing 1 Intake manifold 2 Outlet nozzle 3 chamber 4 chamber 5 turbine 6 Foam lining 7 smooth 7.1 nubbed 7.2 filter 8th Outlet opening for the drive motor 9 Drive motor 10 Opening between the chambers 11 Rubber cuff 12 Turbine intake opening 13 Exhaust turbine 14

Claims (7)

1. Noise-insulating housing for accommodating a turbine of a ventilator, consisting of two completely sealable chambers, the first chamber having an intake port for air and accommodating the turbine and the compressed air being discharged into the second chamber from where it is discharged via an outlet port into an air supply hose to the patient, characterized in that
both chambers ( 4 , 5 ) have a lining ( 7 ) made of foam on all chamber walls,
the first chamber ( 4 ) has an outlet opening ( 9 ) for the drive motor ( 10 ) of the turbine ( 6 ) and
the turbine ( 6 ) is at least elastically mounted in the outlet opening ( 9 ) for the drive motor ( 10 ) and in the opening ( 11 ) which connects the chamber ( 4 ) with the chamber ( 5 ). 2. Sound-insulating housing according to claim 1, characterized in that the lining ( 7 ) of the chamber ( 5 ) consists of dimpled foam ( 7.2 ). 3. Sound-insulating housing according to claim 1 or 2, characterized in that the lining ( 7 ) of the chamber ( 5 ) is designed as an insert into the chamber ( 5 ). 4. Noise-insulating housing according to one of claims 1 to 3, characterized in that the outlet ( 14 ) from the turbine ( 6 ) is arranged in the opening ( 11 ) between the chambers ( 4 ) and ( 5 ) and the outlet nozzle ( 3 ) exits the chamber ( 5 ) laterally offset from it. 5. Sound-insulating housing according to one of claims 1 to 4, characterized in that the lining ( 7 ) of the chamber ( 4 ) opposite the intake opening ( 13 ) of the turbine ( 6 ) is a dimpled lining ( 7.2 ). 6. Sound-insulating housing according to one of claims 1 to 5, characterized in that a rubber sleeve ( 12 ) is arranged in the outlet opening ( 9 ) for the drive motor ( 10 ), through which the drive motor ( 10 ) is inserted. 7. Sound-insulating housing according to one of claims 1 to 6, characterized in that a filter ( 8 ) is arranged in the chamber ( 4 ) in front of the mouth of the intake manifold ( 2 ).