BORALI STEFANO (IT)
| WO1986002820A1 | 1986-05-22 | |||
| WO2004039444A1 | 2004-05-13 |
| US4745796A | 1988-05-24 | |||
| EP1205747A2 | 2002-05-15 | |||
| US6039696A | 2000-03-21 | |||
| EP1329240A1 | 2003-07-23 |
| 1. | 1) A receptacle for sensors (7), the receptacle being insertable in a gas stream, housing at least one sensor (7) for controlling at least one physical/chemical parameter of said gas stream, and comprising at least one boundary wall (8,9) defining the receptacle itself; characterized in that the boundary wall (8,9) is defined at least partly by a filtering element (17) permeable solely to the gaseous phase of said gas stream. |
| 2. | A receptacle as claimed in Claim 1, wherein said filtering element (17) comprises a diaphragm. |
| 3. | A receptacle as claimed in Claim 1 or 2, and having a given longitudinal axis (5); the boundary wall (8,9) being cupshaped and open outwards. |
| 4. | A receptacle as claimed in Claim 3, wherein the boundary wall (8,9) comprises a first wall (8) extending about said axis (5), and a second wall (9) axially defining the receptacle; the filtering element (17) defining at least part of at least one of said first wall and said second wall (8,9). |
| 5. | A receptacle as claimed in Claim 3 or 4, and also comprising means (18) for closing the receptacle in the absence of said sensor (7). |
| 6. | A receptacle as claimed in any one of the foregoing Claims, wherein the sensor (7) is fitted in axially sliding manner to said boundary wall (8,9), and is secured frictionally inside the boundary wall (8,9). |
| 7. | A conduit of a medical respiration support circuit, the conduit comprising a first tubular body (2) along which a ventilation gas stream flows; and a receptacle (6) inserted at least partly inside said first tubular body (2), housing at least one sensor (7) for controlling at least one physical/chemical parameter of said gas stream, and comprising at least one boundary wall (8,9) defining the receptacle (6) itself; characterized in that the boundary wall (8,9) is defined at least partly by a filtering element (17) permeable solely to the gaseous phase of said gas stream. |
| 8. | A conduit as claimed in Claim 7, wherein said filtering element (17) comprises a diaphragm. |
| 9. | A conduit as claimed in Claim 7 or 8, wherein the receptacle (6) has a given longitudinal axis (5); the boundary wall (8,9) being cupshaped and open outwards. |
| 10. | A conduit as claimed in Claim 9, wherein the boundary wall (8,9) comprises a first wall (8) extending about said axis (5), and a second wall (9) axially defining said receptacle (6); the filtering element (17) defining at least part of at least one of said first wall and said second wall (8,9). |
| 11. | A conduit as claimed in Claim 9 or 10, and also comprising means (18) for closing said receptacle (6) in the absence of said sensor (7). |
| 12. | A conduit as claimed in any one of Claims 7 to 11, wherein the sensor (7) is fitted in axially sliding manner to said receptacle (6), and is secured frictionally inside the receptacle (6). |
| 13. | A conduit as claimed in any one of Claims 7 to 12, and also comprising a second tubular body (20) extending about said first tubular body (2) at said receptacle (6) to define an insulating air chamber (21) ensuring correct operation of said sensor (7). |
| 14. | A medical respiration support circuit comprising a conduit (1; 19) as claimed in Claims 7 to 13. |
TECHNICAL FIELD The present invention relates to a receptacle for sensors.
More specifically, the present invention relates to a receptacle for sensors of a medical respiration support circuit, to which the following description refers purely by way of example.
BACKGROUND ART In the medical equipment industry, a respiration support circuit is known comprising a conduit along which a stream of ventilation gas flows; and a cup-shaped receptacle extending at least partly inside the conduit to support a sensor, and designed to separate the sensor from the gas stream in the conduit, so that the sensor can be re-used for another patient without being cleaned, disinfected or sterilized.
Known medical respiration support circuits of the type described above have various drawbacks, mainly due to the receptacle only being designed to house temperature sensors, i. e. sensors whose operation does
not depend on direct contact with the gas stream.
DISCLOSURE OF INVENTION It is an object of the present invention to provide a receptacle for sensors, designed to eliminate the aforementioned drawbacks.
According to the present invention, there is provided a receptacle for sensors, as claimed in Claim 1.
BRIEF DESCRIPTION OF THE DRAWINGS A non-limiting embodiment of the present invention will be described by way of example with reference to the accompanying drawings, in which: Figure 1 shows a longitudinal section of a medical respiration support circuit conduit featuring a preferred embodiment of the receptacle for sensors according to the present invention; Figure 2 shows the same view as in Figure 1, of a variation of the Figure 1 conduit.
BEST MODE FOR CARRYING OUT THE INVENTION Number 1 in Figure 1 indicates as a whole a conduit of a medical respiration support circuit (not shown).
Conduit 1 comprises a tubular body 2, along which a stream of ventilation gas flows, and which has a given longitudinal axis 3, and a hole 4 formed radially through body 2 and having a longitudinal axis 5 crosswise to axis 3.
Conduit 1 also comprises a receptacle 6 for housing at least one sensor 7 controlling at least one physical/chemical parameter of the gas stream in body 2,
and which extends inside body 2 through hole 4 and coaxially with axis 5.
Receptacle 6 is cup-shaped, is open outwards, is defined laterally by a substantially cylindrical wall 8 coaxial with axis 5, and is closed axially by a bottom wall 9 substantially perpendicular to wall 8 and to axis 5.
Wall 8 has an annular flange 10 substantially coaxial with axis 5, projecting radially outwards from the outer surface of wall 8, and which contacts body 2 when receptacle 6 is inserted axially inside hole 4; and wall 8 has an outside diameter approximately equal to but no smaller than the diameter of hole 4, so as to secure receptacle frictionally inside hole 4.
Sensor 7 comprises a sensitive element 11 inserted inside a tubular body 12, which is fitted inside receptacle 6, coaxially with axis 5, and comprises a wide portion 13, and a narrow portion 14 defined by a grille for protecting sensor 7, and which, together with receptacle 6, defines a chamber 15.
Portion 13 has an annular flange 17 substantially coaxial with axis 5, projecting radially outwards from the outer surface of portion 13, and which contacts wall 8 when body 12 is inserted axially inside receptacle 6; and portion 13 has an outside diameter approximately equal to but no smaller than the inside diameter of wall 8, so as to secure body 12 frictionally inside receptacle 6.
Wall 9 is defined by a permeable diaphragm 17, which permits the passage of gaseous phases, prevents the passage of solid and liquid phases, such as bacteria, viruses, water droplets, dust particles and/or biological fluids, and so only permits passage into chamber 15 of the gaseous phase of the gas stream in body 2, thus ensuring correct operation of sensor 7.
Receptacle 6 also has a cap 18, which is inserted into the free end of receptacle 6 in the absence of sensor 7.
The Figure 2 variation relates to a conduit 19, which only differs from conduit 1 by receptacle 6 being formed in one piece with body 2, and by the presence of a second tubular body 20 fitted, coaxially with body 2, at receptacle 6 to define, together with body 2, an annular insulating air chamber 21 for ensuring correct operation of sensor 7.
Body 20 comprises two substantially semicylindrical shells 22, 23-of which, shell 22 is fitted through with receptacle 6-which are fitted in axially fixed manner to body 2, and are connected to each other by known fastening means not shown.
In variations not shown, diaphragm 17 may obviously define at least part of lateral wall 8 of receptacle 6.
Receptacle 6 therefore has the advantage of being able to house all types of sensors 7 for controlling physical/chemical parameters of the patient's ventilation gas stream, such as temperature, pressure, humidity, and oxygen and/or carbon dioxide concentration sensors.