DE202006007397U1 - Ventilation hose with different heating zones - Google Patents

Abstract

heated Hose for the transport of humidified, tempered gases through different Climate zones to or from the patient in the context of respiratory therapy or Ventilation, characterized in that the tube at least two Hose sections with different effective heating capacity on the hose length having.

Description

Summary

heated Hose for the condensate-minimized transport of tempered, moist gases through different climates to or from the patient in the context of Respiratory therapy or ventilation, characterized in that the hose out at least two hose sections with different effective Heating capacity based on the hose length exists.

description

The The invention relates to a heated breathing tube for operation a ventilator in conjunction with an active humidifier and an infant incubator.

State of the art

in the Frame of the artificial Ventilation or respiratory therapy of patients come with breathing circuit systems for use. about this supplies the patient with the gas mixture delivered by the ventilator.

One Ventilation tube system usually consists of a so-called inspiratory tube, the supplying the patient with "fresh" gas, and a so-called expiratory tube, which is responsible for the removal of carbon dioxide enriched exhaled gas back to the ventilator and is used in the environment. The control and monitoring the gas flows done by the ventilator.

a Special case represents the ventilation therapy of premature and newborns, the often within so-called infant incubators ("Incubator") takes place with the Aim, a warmth-neutral environment for the to ensure temperature-sensitive organisms of this patient group.

The ventilators themselves are typically outside the incubator. The breathing tubes from the ventilator to the patient thus inevitably run through different Climate zones: outside the incubator prevails room temperature while the air temperature within of the incubator is set to a specific target value. This is usually between about 30 ° C and 37 ° C and is set for each patient.

The the patient from the ventilator supplied Gas mixture must in many cases warmed before entering the respiratory tract and moistened to prevent lung and mucous membrane damage To prevent dehydration. For this is usually a corresponding Respiratory gas humidifier is used in which the dry gas of the respirator is initiated. This afterwards heated and humidified gas is then released from the outlet of the humidifier Patients headed. Since in this process energy in the form of Humidity and heat supplied externally is, one speaks of an active Atemgasanfeuchtung.

Around the condensation of the moisture introduced into the respiratory gas the breathing tubes To prevent these are usually in such an application with a heater provided. To monitor the energy delivery to the patient there is a near-patient temperature measurement, the heating power into the breathing tubes integrated heating regulates.

One regular problem in this application is the presence of different climates, if breathing tubes equipped with only one temperature probe and above all only one heater are whose heating energy is over the entire hose length is consistent. The problem as such consists predominantly in the formation of condensate in the breathing tubes, what for many reasons undesirable is.

Next The hygienic problem can be the presence of large quantities of condensate in breathing tubes lead to technical difficulties in ventilation, e.g. in the form of falsified Measurements, which in turn lead to unwanted actions of the ventilator. can.

was standing the technology to the solution These problems are different approaches, but all of them unsatisfactory are.

at Most known systems are heated by the hose only outside of the incubator while complete the hose sections inside the incubator are unheated. The measurement of the gas temperatures takes place on the Inspiratory site either close to the patient in the area of the so-called Y-piece (Junction of patient, inspiratory and expiratory tubing) or outside of the incubator.

in the Case of near-patient measurement is the problem on the inspiratory side, that the temperature target value of the patient to be applied Gases under unfavorable Conditions is not reached.

Especially at low incubator temperatures, the temperatures required for condensate avoidance can be heated even by overheating the gas in the outside th hose areas are not achieved in many cases.

On On the expiratory side, this problem is even more serious. Here it comes with unheated hose sections within the Incubators regularly for Formation of condensate as soon as the incubator is at temperatures below the gas saturation temperature is set. This is often the case in practice, since the gas saturation temperature of the patient's exhaled gas, e.g. just under 37 ° C, the Incubator but often at temperatures well below (e.g., 33 ° C).

The Using continuously heated hoses is also problematic. Lead on the inspiration page the higher compared to the environment Air temperatures in conjunction with the heated hose to a rapid achievement of the temperature target value with the consequence of a limitation the heating power. However, this heating power is for the outside of the incubator and thus in the cooler Environmentally located hose sections often insufficient to the Avoid condensation. On the expiration side exists the danger that at high incubator temperatures the tube wall quickly the maximum allowable Surface temperature exceeds.

task

task The present invention is the problem of condensate formation in the presence of different climates. there should the heated breathing tube inexpensive to produce and be reliable.

These Task is inventively achieved by a heated breathing tube, which has several sections with different lengths relative to each other Heating capacities. The invention has the advantage that by reducing the effective heat output in the area within the incubator lying hose sections a compensation of the existing there additional Thermal energy occurs due to compared to room temperature higher Inkubatorinnentemperatur.

A Variation of the effective heating power based on the hose length can be reach through a variation of the by the hose heater electrically generated heating power and by a variation of the thermal Isolation of the different hose sections. This includes one Variation of the technical design of the hose heater with a, e.g. through a heating coil lying in the hose inner lumen can be realized or through a in the hose wall integrated heating coil.

The Variation of the electrically generated effective heating power related on the hose length in the individual tube sections can be realized by different resistance values of the individual heating wires or by operation with different heating voltages or duty cycles or by a different winding density of the heating coils at same resistance value.

embodiments

Further advantages and features will become apparent from the following description of an embodiment:
It shows

1 the basic structure of a breathing circuit in an incubator. This has an inspiratory tube into which the gas heated and humidified by a breathing gas humidifier is introduced and an expiratory tube. Patient, inspiratory and expiratory tubes are connected to each other via a Y-piece.

2 the electrical design of an inspiratory tube in detail

The inspiratory tube in 1 (consisting of the parts 1 - 5 ) is made by means of the connection sleeve 1 to the gas outlet of the humidifier 21 connected. The heated and humidified gas flows through the first part of the heated hose 2 and it will correspond to the colder ambient temperature compared to the temperature within the incubator 12 maintained at a higher heat output per hose length to temperature or heated. In the connecting sleeve 3 is the second hose part 4 electrically with the first 2 connected so that the heating wires are connected in series ( 2 ). By choosing the heating wire resistors, the heating power in the partial areas can thus be set differently. At a resistance of eg 24 ohms in the first tube section 2 and a resistance of eg 3 ohms in the second tube section 4 So different heating outputs per hose length can be delivered. The gas flows through the second hose part accordingly 4 , which is operated with a lower power per hose length. By means of the connection sleeve 5 becomes the inspiratory tube with the Y-piece 6 connected. In this sleeve are the temperature sensor 16 and the connection line 15 integrated for sensor and heating wires. In an alternative embodiment, the sensor could also be used as a separate component with its own connecting line in the sleeve 5 or the Y-piece 6 be inserted, whereby the connecting line for the heating wires then in the sleeve 1 could be integrated.

The gas flows through the Y-piece 6 in the patient 19 , During expiration the gas flow is reversed and it flows through the expiratory tube (consisting of the parts 7 - 11 ) back to the exhalation port of the ventilator 20 back.

The expiratory tube is basically the same structure as the inspiratory tube and thus consists of a near-patient connection sleeve 7 , Hose piece with low heat output 8th , Coupling sleeve 9 , Hose piece with higher heat output 10 and device-side connection sleeve 11 , The difference lies in the placement of the sensor and the connecting cable. Preferably, both are in the sleeve 11 integrated, wherein the sensor can also be a separate plug-in sensor here.

2 shows the electrical design of an inspiratory tube in detail. The heated pieces of hose 2 and 4 are preferably designed so that 2 Parallel heating wires (2 · 17 in the hose section with lower heating power 2 and 2 x 18 in the hose section with higher heat output 4 ) are integrated in the tube wall. In the sleeves ( 1 and 3 ), the heating wires are connected according to the diagram. Into the patient-side connection sleeve 5 is preferably the sensor 16 directly integrated, leaving only a common 4-wire connection cable 15 needed for sensor and heating. This is about the plug connection 14 with the control unit 13 connected. By choosing the heating element, the heating power ratio of the hose sections 2 and 4 to each other.

In a further embodiment can the different effective heat output of different Hose sections also by a different effective thermal Isolation and thus influencing the effective heating power same nominal electrical heating power done.

In a further embodiment can on a coupling sleeve between the different tube sections be dispensed with and a different effective heating capacity achieved by a different effective length of the heating coils become. It could the effective length the heating coil in the stronger heated hose section e.g. be enlarged by a closer winding. In less tube section to be heated then the heating coil with the same pass nominal resistance per length in a less tight winding and so by a shorter effective Length for a reduced provide electrothermal energy release.

In a further embodiment can the different effective heat output of different Hose sections also by a different arrangement of Heizwendel done (for example, located within the hose lumen heating coil versus out-of-town Heating coil).

deviant of these embodiments Various modifications and modifications are possible without deviate from the spirit of the invention. Therefore, the scope of protection by the following claims and set their equivalents:

1

coupling bush Inspiratory tube to the ventilator

2

heated Part of the inspiratory tube with higher heat output

3

junction

4

heated Part of the inspiratory tube with lower heating power

5

patient-side Connection sleeve of the inspiratory tube

6

Y-piece

7

patient-side Connection sleeve of the expiratory tube

8th

heated Part of the expiratory tube with lower heating power

9

junction

10

heated Part of the expiratory tube with higher heat output

11

coupling bush Exhalation tube to the ventilator

12

incubator

13

Tax- and control unit

14

electrical connection

15

4-core connection cable

16

temperature sensor for measuring the gas temperature

17

heating wire with lower power output / ohms per length

18

heating wire with higher Output power / ohms per length

19

patient

20

ventilator

21

humidifier

Claims (13)

Heated tube for the transport of humidified, tempered gases through different climatic zones to or from the patient in the context of respiratory therapy or ventilation, characterized in that the hose has at least two tube sections with different effective heating power based on the hose length. Hose according to claim 1, characterized in that for the different effective heating performance per hose length different heating voltages for the heating wires in the individual tube sections are provided. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that for the different effective heating capacity per hose length at least a switching element is provided for different duty cycles the heating wires in the individual tube sections. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that the different effective heating power per hose length is realized by heating wires with different electrical resistance per wire length. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that per hose length different effective thermal insulation is provided. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that the hose with different lengths heating wires in terms of hose length in the different tube sections is provided. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that the different effective heating power per hose length is realized by the use of different Heizdrahtanordnungen in the different tube sections. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that the hose consists of several sub-hoses, which are mechanically and / or electrically connected to each other. Hose according to claim 1 according to one or more of the preceding claims, characterized in that the heating zones ( 17 and 18 ) from a single energy source or control unit ( 13 ), preferably by means of electrical series connection. Hose according to claim 1 according to one or more of the preceding claims, characterized in that the total of several sections of existing hose for heating only a single electrical connection ( 14 ) for connection to a power source or a control unit ( 13 ) having. Hose according to claim 1 according to one or more of the preceding claims, characterized in that it has a temperature sensor for controlling the heating power ( 16 ) has at the end of the last tube section in the flow direction. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that for different heating outputs separate control circuits are provided. Hose according to claim 1 according to one or more of the aforementioned Claims, characterized in that as an input variable for the control of the heating power a mathematical algorithm is used.