DE9102784U1 - Temperature sensors for medical applications - Google Patents

Description

Temperature sensors for medical applications

The innovation relates to a temperature sensor according to the generic term of protection claim 1.

Temperature sensors are required for a wide range of medical applications, especially in areas where a high level of sterility is required to prevent infections. Examples of such applications are temperature sensors for measuring gas or liquid media.

In order to be able to connect such electrical temperature sensors to the measuring or control devices, flexible measuring cables are necessary, which in turn require flexible electrical insulation for the conductors. If special materials are not used for this electrical insulation, but rather the usual materials such as rubber or elastic plastic, this has the disadvantage that known temperature sensors can only be sterilized by wiping disinfection, which often means that the requirements for germ-freeness or sterility cannot be optimally met.

The aim of the innovation is to demonstrate a temperature sensor for medical applications that is autoclavable despite the use of conventional materials for the insulation of the measuring line.

To solve this problem, a temperature sensor is designed according to the invention in accordance with the characterizing part of claim 1.

The particular advantage of the new temperature sensor is that the measuring line can be separated from the actual temperature sensor and that after separating the measuring line from the temperature sensor, no lines with a

flexible electrical insulation and can therefore be made entirely from a heat-resistant or autoclavable material.

Further developments of the innovation are the subject of the dependent claims.

The innovation is explained in more detail below using the figure, which shows an autoclavable temperature sensor according to the innovation in a simplified representation and partly in section.

In the figure, 1 is a connector of a medical hose for a medium, for example for breathing air. An electrical temperature sensor 3 is inserted in the connector 1 to measure the medium flowing through this connector and the hose 2, which is connected via a flexible electrical line 4 to a measuring or control device (not shown in detail).

The actual active element of the temperature sensor 3, i.e. the element that responds to different temperatures, is a temperature sensor 5 in the embodiment shown, which projects with its active area 5' over the underside of the temperature sensor 3 or a housing 6, in such a way that the temperature sensor 5 or its area is essentially coaxial with the central axis of the sleeve-like housing 6. The sensor 5 is selected so that it can be autoclaved at both 121° C and 134° C. The housing 6 has projections 7 at its lower end that project beyond the underside there, which are provided on an imaginary circular line at a distance around the area 5'. In the embodiment shown, three projections 7 are provided, each distributed by 120° around the central axis of the housing 6. The projections 7 protect the area 5' of the sensor 5 against the effects of force to the greatest possible extent. A sufficient distance between the projections 7 and the area 5 ¹ ensures that the area 5' is surrounded by the respective medium whose temperature is to be measured.

can be flowed around to a sufficient extent. At the upper end of the housing, which is provided with a protruding flange 8, a mini plug socket 9 is provided in the housing, the connections of which are electrically connected directly to the connections 10 and 11 of the temperature sensor 5 in a suitable manner. The housing 6 consists of a temperature-resistant or autoclavable plastic, preferably polysulfone. The temperature sensor 5 and the plug socket 9, the electrically insulating parts of which are also made of a temperature-resistant or autoclavable material, for example plastic, are embedded and fixed in the sleeve-like housing 6 using a hardenable and, after hardening, heat-resistant or autoclavable and, in particular, also electrically insulating material, for example with the aid of an epoxy resin formulation. The measuring line 4 is connected to the temperature sensor 3 or to its temperature sensor 5 via a plug 12 that fits into the plug socket 9. The plug socket 9 and the plug 12 are preferably designed in such a way that the plug 12 is secured against unwanted slipping out after insertion into the plug socket 9 by spring-loaded engagement or by locking.

Since the direct connection between the temperature sensor 5 and the plug socket 9 means that no electrical cables with insulation are required and, in addition, both the housing 6 and the plastic mass holding or embedding the temperature sensor 5 and the plug socket 9 in the housing are heat-resistant or autoclavable, and, in addition, since the measuring line 4 can be separated from the temperature sensor 3 by the plug connection formed by the plug socket 9 and the plug 12, the temperature sensor 3 is autoclavable in order to achieve the highest requirements with regard to freedom from germs and sterility.

The innovation has been described above using an example embodiment. It goes without saying that changes and modifications are possible without thereby departing from the inventive concept underlying the innovation.

In particular, the temperature sensor 3 is not limited to use with a connector 1 for medical hoses, but can be used anywhere where temperature measurement is required for sterile media.

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List of reference symbols

1 Connector 2 Hose 3 Temperature sensor 4 Measurement line 5 Temperature sensor 5 ¹ Area 6 Housing 7 head Start 8th flange 9 Socket 10 Connection 11 Connection 12 Plug

Claims (8)

Protection claims 1. Temperature sensor for medical applications, with an electrical sensor (5) arranged in a housing (6) and with an electrical, flexible measuring line (4) connected to the sensor (5), characterized in that the sensor (5) is connected with its connections (10, 11) to a first coupling element (9) of an electrical coupling provided on the housing (6), that the measuring line (4) is provided with a second coupling element (12) of the electrical coupling, and that the first coupling element (9) and the sensor (5) are fixed in the housing (6) consisting of a heat-resistant or autoclavable material by means of a heat-resistant or autoclavable and electrically insulating mass. 2. Temperature sensor according to claim 1, characterized in that the first coupling element is a plug socket (9) and the second coupling element is a plug (12). 3. Temperature sensor according to claim 1, characterized in that the first coupling element is a plug and the second coupling element is a plug socket. 4. Temperature sensor according to one of claims 1-3, characterized in that the housing (6) is designed like a sleeve, and that the sensor (5) with an active area (5') protrudes beyond one end of the housing (6), and that the first coupling element (9) is provided in the area of the other end of the housing (6). 5. Temperature sensor according to one of claims 1-4, characterized in that the sensor (5) projects with an active region (5 ¹ ) beyond a surface of the housing (6), and that on this surface of the housing (6) a plurality of projections (7) surrounding the active region (5') of the sensor (5) are provided. 6. Temperature sensor according to one of claims 1-5, characterized in that the housing (6) consists of plastic. 7. Temperature sensor according to one of claims 1-6, characterized in that the mass embedding the sensor (5) and the first coupling element (9) is a plastic. 8. Temperature sensor according to one of claims 1-7, characterized in that the coupling elements (9, 12) are designed to engage resiliently with one another or to be interlocked with one another.