DE19958296C1 - Heated breathing tube for patient has heating element formed by tube wall and consisting of layer of electrically conductive synthetic material, voltage supply line integrated into tube wall - Google Patents

Abstract

The device has a flexible tube wall (1) and a heater with a heating element made of electrically conductive synthetic material (a). The heating element is formed by the tube wall and consists of a layer of the electrically conductive synthetic material. The conductive layer can be arranged in the inner region of the tube wall or in its outer region and a voltage supply line is integrated into the tube wall.

Description

The invention relates to a heatable breathing gas hose with a flexible Material formed hose wall for supplying a breathing gas to a patient.

From DE 42 44 493 A1 a heatable breathing gas hose is known which consists of a rubber-elastic material is made and in the area of its outer surface with is provided helical electrical heating wires.

From DE 196 17 095 C1 a similar hose is known in which the Heating wire spiral is arranged in the interior of the hose. This results in a improved heat transfer between the breathing gas and the heating wires. With this Conventional hose has the problem that it can only be compared can be cleaned with great effort and also a considerable respiratory resistance is produced. The embedding of the heating wire spiral prepares under manufacturing technology Viewpoints difficulties.

The invention has for its object an easy to handle, heatable Breathing gas hose to create a supply of breathing gas to a patient which with a comparatively low benefit is one to avoid Adequate heating of the hose wall is achieved can be and which is inexpensive to manufacture from a manufacturing point of view leaves.  

This object is achieved by a heatable hose Delivery of a breathing gas to a patient with one made of a flexible material formed hose wall and a heating device, the heating device Has heating element which is formed from an electrically conductive plastic material.

This advantageously makes it possible to create a highly flexible hose in which the hose wall is evenly at a temperature above the Dew point of the breathing gas in particular to a temperature in the range of approx. 35 ° C can be heated.

According to a particularly preferred embodiment of the invention, the heating element is formed directly by the hose wall. This makes it possible to Avoidance of condensation necessary heating under one to achieve extremely low temperature gradients.

It is also possible to electrically heat the heating element through a preferably thin layer to form conductive plastic material. The thickness of this layer is preferably in Range from 0.3 to 1.2 mm.

An embodiment which is advantageous with regard to a particularly low energy consumption the invention is given in that the conductive layer in the interior of the Hose is arranged. As a result, the gas is immediately in contact with the breathing gas stepping wall heated, so that the precipitation of moisture here particularly is reliably avoided. The hose wall located further out is suppressed continue to transport heat outside.

As an alternative to the solution described above, it is also possible, however provide a conductive layer in the outer tube area. This can be advantageous the conductive layer can be shrunk onto the hose.

The voltage supply takes place according to a particularly preferred embodiment the invention by a power supply line in the hose wall  is integrated. Such integration can be achieved in particular by the fact that the power supply line through a spiral spiral stiffening the hose is formed.

A particularly favorable voltage supply can be achieved that at least two axially spaced spiral spirals are provided. This will make it possible, even with a comparatively high electrical resistance of the conductive Plastic material with a low supply voltage sufficient heat to ensure the hose. The discharge path corresponds here preferentially only the distance between two lead wires, especially spiral coils.

According to a particularly preferred embodiment, the spiral spirals are the inven tion formed from an electrically conductive plastic material. It is also possible that Form spiral coil so that they are essentially as power supply lines are effective and only a comparatively small voltage drop in the spiral spirals he follows. This can be achieved in particular in that a Metal wire is embedded.

A particularly advantageous coupling of a heatable breathing gas hose, in particular special with the features described above can according to a particular preferred embodiment of the invention achieved by a hose connector device with a contact element for electrical coupling of the heating element with a Voltage source.

The hose connector device preferably has a first connection mouth for the Breathing gas channel and a second connection mouth for a pressure measuring channel. This also makes it possible directly by connecting the breathing gas hose to achieve a corresponding coupling of a pressure detection line.

The contact element is advantageously in the region of one of the connection openings provided which results in a particularly compact connector structure.  

Further details and features of the invention emerge from the following Description of several preferred embodiments in connection with the drawing mentions. Show it:

Fig. 1: a simplified detailed view for explaining the structure of a breathing gas hose with a hose formed from a conductive plastic material, which is supplied with voltage via two separate spiral inserts;

FIG. 2 is a simplified sectional view through a respiratory gas tube, wherein in the region of the outer tubular wall a layer formed from an electrically conductive plastic is provided, which is also supplied by two separate conduit means with voltage;

FIG. 3 shows a simplified sectional view through a respiratory gas tube with an attached in the interior of which the electrically conductive plastic layer;

Fig. 4: a simplified sectional view for explaining the structure of a further ren preferred embodiment of a breathing gas hose with an electrically conductive inner layer and a separate voltage supply line;

FIG. 5 is a perspective view of a portion of a breathing gas hose with two spiral coils;

Fig. 6 is a perspective view of a connector plug means to Ankop pelung a breathing gas hose to a CPAP device, or to a humidifier;

FIG. 7 is a simplified sectional view also by a connector for coupling a breathing gas hose to a CPAP device with a directly on the device side provided spigot taking place voltage supply;

Fig. 8 is a simplified sectional view showing the power supply of a breathing gas hose with an electrically conductive Schlauchinnenwandung via an electrically conductive hose connection pin and a tube inserted here in the respiratory gas separate lead wire;

Fig. 9 is a simplified sectional view of a connector assembly for coupling an electrically heatable respiratory gas tube and a coaxially guided pressure therein, in which case the power supply is also done meßschlauches to a CPAP device via the device side provided for connection piece.

The breathing gas hose shown only in sections in Fig. 1 comprises a Rohrwan extension 1 , which is formed here from an electrically conductive plastic material a. The breathing gas hose is further provided with a first reinforcement insert 2 and a second reinforcement insert 3 . The two reinforcing inserts are formed here from an electrically conductive material and coupled to a voltage source with the interposition of a control device. Due to the potential difference between the two line devices 2 , 3 , an electrical discharge takes place via the electrically conductive plastic material a. As a result of the electrical discharge taking place with a corresponding potential difference, the plastic material a and thus the hose wall 1 are heated. In the embodiment shown here, the two line devices are formed by a spiral spiral, as is indicated in a simplified manner in FIG. 5. The distance between the two line devices 2 , 3 is essentially constant over the entire hose element, so that with a negligibly small voltage drop along the spiral coil between the spiral coils a heat output which is almost constant in each case is released.

In the embodiment shown in FIG. 2, the electrically conductive layer a forms only part of the hose wall 1 delimiting the actual breathing gas channel 4 . The electrically conductive layer is shrunk here in the manner of a shrink tube on the outside area of the breathing gas tube and thereby comes into intimate contact with the line devices 2 , 3 , which, similarly as already in connection with the embodiment according to. Fig. 1 described, are formed from an electrically conductive material. In this embodiment too, the electrically conductive layer a is heated as a result of a potential difference between the line devices 2 , 3 . The level of this potential difference can be influenced by a control device. In the embodiment shown here, it is provided that the electrically conductive hose wall is heated by a direct voltage of approximately 4 volts. It is also possible to apply an AC voltage to the corresponding line devices instead of a DC voltage. When using an alternating voltage to heat the hose wall, it is possible to use plastic materials which only have sufficient conductivity when an alternating voltage is applied.

In Fig. 3, a further preferred embodiment of an electrically heated breathing gas hose is shown, in which the heating of the hose wall is achieved by an electrically conductive layer a attached in the inner region of the breathing gas hose. The voltage supply can take place via separate line devices or at least partially via a reinforcing insert 2 , which in the embodiment shown is also formed from an electrically conductive plastic material.

FIG. 2 shows a further embodiment of a breathing gas hose, which has a hose wall 1 formed from an insulating plastic material, which is also reinforced with a spiral insert 2 . In the embodiment shown here, however, the spiral insert 2 is not integrated into the electrical circuit. The voltage supply to the electrically conductive layer a provided here in the inner region of the breathing gas tube is provided by a separate lead wire 5 , which is inserted here into a pressure measuring tube 6 . This lead wire 5 is coupled to the electrically conductive layer a in the region of the mask-side end of the breathing gas hose. The electrical circuit is closed by the electrically conductive layer a in the area of the CPAP device coming into contact with a corresponding terminal arrangement.

In Fig. 5, as already mentioned in connection with FIGS. 1 and 2, a breathing gas tube is shown, which was reinforced by two spirally guided in the outer tube area A layers 2 , 3 . These inserts can - as described in FIGS. 1 and 2 - be designed as voltage supply lines, so that an electrical discharge takes place in the intermediate area between the adjacent sections of the reinforcing inserts.

In FIG. 6, a preferred embodiment of the compact connector for connecting a heatable respiratory gas tube to a CPAP device is illustrated. In the embodiment shown here, the voltage supply to the electrically heatable breathing gas hose takes place via two contact elements 7 , 8 , which are embedded here in the plug structure. The contact elements 7 , 8 are electrically connected to the further circuit of the breathing gas hose via line devices, not shown here. The compact connector shown here comprises a first connection mouth 9 , via which the actual breathing gas passage channel can be coupled more wetly to a CPAP device or to a breathing gas. Radially spaced from this first connection mouth is a second connection mouth, via which a pressure measurement hose, which is not otherwise shown here, can be coupled with a pressure measurement system of a CPAP device. The compact plug shown here is also made of a silicone material and can be cleaned and, in particular, sterilized together with the breathing gas hose. In the embodiment shown here, the wall 1 of the breathing gas hose is formed from an electrically conductive plastic material.

Fig. 7 shows a further embodiment is shown a connector plug for connecting a heatable respiratory gas tube to a CPAP device, wherein the contact elements are arranged in the interior of the plug connector 11 different from that described in Fig. 6 embodiment. The power supply is in this case in particular via contact elements 7 b, 8 b which are engageable with the device side provided connecting pieces 12, 13 in connection, wherein these device-side connection piece 12, at 13 least are sections designed to be electrically conductive so that clip, this connection a corresponding Connection to a device-side power supply can be achieved. The contact elements 7 b, 8 b are coupled to the electrically heated breathing gas hose via connecting lines 14 , 15 . In the embodiment shown here, the breathing gas hose has an electrically conductive layer a in the region of its inner wall as well as also electrically conductive spiral reinforcement helix 2 . In the area of the mask-side end of the breathing gas hose, the last turn of the electrically conductive reinforcing insert is electrically connected to the electrically conductive layer a.

In FIG. 8, another embodiment of an electrically heatable respiratory gas is shown hose, in which case the respiratory gas tube - as already mentioned in connection with Fig. 4 - which only has an electrically conductive inner layer a and the power supply otherwise via a separate conduit means. In the embodiment shown here, in the area of the CPAP device, an electrical connection to the conductive layer a is achieved by a connecting piece 12 formed from a metal material. In the area of the mask-side end, a connecting piece 17 is also provided, which can also be coupled here to the electrically conductive layer a, in particular can be inserted into the breathing gas hose. This connecting piece 17 is electrically conductive coupled to a voltage supply line 5 , which is inserted here in a pressure measuring tube 6 . The voltage supply line 5 extends through the pressure measurement hose 6 to the CPAP device and is also coupled here to a corresponding voltage source.

In Fig. 9 a further connector structure for connecting an electrically heatable breathing gas hose to a CPAP device is shown. The electrically heated breathing gas hose provided here comprises an electrically conductive layer formed from an electrically conductive material, which layer can be coupled to a voltage supply line 19 provided by a CPAP device. The coupling takes place here via a contact element 20 , which is embedded in a connector structure 21 and is connected to the electrically conductive layer a of the breathing gas hose. Coaxially in the interior of the connector structure 21 there is a connection structure 22 for a pressure measurement hose, via which at the same time the conductor 5 guided in the pressure measurement hose 6 is coupled to a voltage supply line 22 on the CPAP device side.

Claims (12)

1. Heated hose for supplying a breathing gas to a patient with a hose wall formed from a flexible material and a heating device, wherein the heating device has a heating element which consists of an electrically conductive Plastic material is formed. 2. Heated hose according to claim 1, characterized in that the Heating element is formed by the hose wall. 3. Heated hose according to claim 1 or 2, characterized in that the Heating element is formed by a layer of the electrically conductive plastic material. 4. Heated hose according to at least one of claims 1 to 3, characterized characterized in that the conductive layer is arranged in the inner region of the hose. 5. Heated hose according to at least one of claims 1 to 4, characterized characterized in that the conductive layer is provided in the outer tube area. 6. Heated hose according to at least one of claims 1 to 5, characterized characterized in that a power supply line in the hose wall is integrated. 7. Heated hose according to at least one of claims 1 to 6, characterized characterized in that the voltage supply line is formed by a spiral coil is. 8. Heated hose according to at least one of claims 1 to 7, characterized characterized in that at least two axially spaced spiral spirals are provided.   9. Heated hose according to at least one of claims 1 to 8, characterized characterized in that the spiral coil made of an electrically conductive plastic material is formed. 10. Heated hose for supplying a breathing gas to a patient with a hose wall formed from a flexible material and a heating device, wherein the heating device has an electric heating element, according to at least one of claims 1 to 9, characterized by a hose connector device a contact element for the electrical coupling of the heating element with one a voltage source provided by a CPAP device. 11. Heated hose according to claim 10, characterized in that the Hose connector device a first connection mouth for the breathing gas channel and has a second connection mouth for a pressure measuring channel. 12. Heated hose according to claim 11, characterized in that the Contact element is provided in the area of one of the connection mouths.