DE3617723A1 - Device for monitoring an intravenous drip - Google Patents

Abstract

The invention relates to a device for optically monitoring the drip frequency in the drip chamber (6) of an infusion apparatus. According to the invention, an optical fibre (10) is arranged in the drip chamber (6) with its free end (12) below the outlet opening (80) of a drop former (8). An optical feedthrough (14) is used to connect the optical fibre (10) optically via a fibre optic coupler (18) to a light source (20) and to an optoreceiver (22), which are linked to an electronic device for monitoring the drip frequency. The effect of these measures is both to reduce the sensitivity of the device with respect to vibrations or tilting of the drip chamber (6), and largely to eliminate the influence of external electromagnetic signals. Furthermore, the device according to the invention is independent of the optical transparency of the drip chamber (6). <IMAGE>

Description

The invention relates to a device for optical monitoring of the drip frequency in the Drop chamber of an infusion device.

From the US patent 40 38 982 is a device to monitor and control the drip frequency of a Infusion device, which is in a drop chamber a bottle containing infusion liquid de drops are registered optically. The optically Transparent drop chamber is in an off for this saving a drop detector used, the one Contains light source and a light receiver, which the Art are arranged opposite each other that one in the Drop chamber dropping drops of light out spread between the light source and the light receiver ger bothers. The signal registered on the light receiver reduction becomes electrical to an electronic Control circuit forwarded the additional an electromagnetic arranged in the infusion line table valve for regulating the drip frequency controls.

From the European patent application EP-A2 01 21 406 an optical drop detector is known that just if built on the principle of a light barrier is, but instead of one at the drop chamber arranged light receiver that from the light source emits light after passing through the drops chamber is coupled into an optical fiber,  the one with one in a control device Light receiver is optically connected. By that measure The coupling of the electric field is taken originals during the signal transmission from the drop detector to the control device prevented, and at required potential freedom in medical applications guaranteed.

In the known devices are light source and Light receiver arranged outside the drop chamber, so that the light emitted by the light source Must cross the housing wall of the drop chamber twice, to get to the light receiver. this leads to Sources of error as both vibrations of the housing, as well as a reduction in the transparency of the housing wall that can arise if the inner wall with Splashes of liquid is wetted or when part of the substance dissolved in the infusion solution the inner wall precipitates, trigger a false report can. In addition, an inclination of the drop chamber cause the drop to drop with the Light path of the light beam of the light barrier no longer cuts.

The invention has for its object a Vorrich device for optical monitoring of the drip frequency in the Specify drop chamber of an infusion device, the regardless of the optical transparency of the housing wall of the drop chamber and its sensitivity to over an inclination and vibration of the drop chamber is reduced. The influence of electromagnetic external signals are largely eliminated and Potential freedom can be guaranteed.  

This object is achieved with the Merk paint the claim 1. The at the outlet of the droplet forming drops wets the free End of the optical fiber and changed the Reflection conditions for that from the light source light propagating to the fiber end. The relationship between the refractive indices of the light guide material and the medium surrounding the free end as well as the The shape of the free end determines the proportion of the in the Optical waveguide of reflected light. Will that free end of the optical fiber from a drop stirs, this ratio is small and large Part of the incoming light emerges from the light waves head out. After the drop from the free end of the optical waveguide is the proportion of light reflected back into the optical waveguide corresponding to the higher ratio between the Refractive indices larger. By means of a suitable electronic device can be on the light receiver measured changes in intensity of the reflected Light measured and for monitoring the drip frequency be used.

In a preferred embodiment, the light is there waveguide made of a polymeric material, in particular their polymethacrylic acid methyl ester PMMA and the free The end of the optical fiber has the shape of a Body of revolution with a curved envelope, its height is larger than the radius of the optical waveguide. There is achieved by that after detaching the drop from free end of the optical fiber in the case of a loading wetting with a thin film of liquid the geo metric shape of the fiber end is little changed because one remaining thinner after detaching a drop Liquid film evenly surrounds the free end.  

The electronic device for identification and about monitoring of the drip frequency contains in a preferred Embodiment a pulse generator that the light source controls. The light source thus emits ge pulsed light. A pulse mode in which the pulse duration is small compared to the temporal pulse interval, is too casual because it is a slow process and no short reaction times are required. In order to with a small average power loss, the An requirements for the optoelectronic components wrestles. By means of a DC coupling of the signal measured at the light receiver is excluded the one caused by ambient light sources Uniform light component eliminated. Through the coincidence stage, the outputs of the Schmitt trigger and the The pulse generator can also be linked together Alternating light component from external light sources, at for example, the alternating light portion of fluorescent roar, be suppressed.

To further explain the invention reference is made to the Drawing referenced in their

Fig. 1, the device according to the invention is shown schematically in section.

Fig. 2 shows a particularly advantageous embodiment of the free end of the optical fiber just if in section and in

Fig. 3, the electronic device for determining and monitoring the drip frequency is illustrated schematically.

Referring to FIG. 1 a container filled with an infusion fluid container 4 2, for example an infusion bottle is connected via a drop former 8 having a chamber 6 drops. The drop chamber 6 is arranged approximately vertically below the container 4 . The Ge wall of the drop chamber 6 consists of an optically transparent material, for example a polymer, preferably made of polymethacrylic acid methyl ester PMMA or polycarbonate PC. The drop chamber 6 is connected to an infusion tube 60 which transports the infusion liquid 2 to the patient's vein. Drops 82 form at the outlet opening 80 of the drop former 8 located in the drop chamber 6 . The free end 12 of the optical waveguide 10 be located immediately below the outlet opening 80 of the drop former 8 . This ensures that even with a drop inclined towards the vertical chamber 6 of the drop 82 formed at the outlet opening 80 comes into contact with the free end 12 of the Lichtwellenlei age 10 . In a preferred embodiment, the optical waveguide is attached to the housing wall by means of an optical feedthrough 14 . The optical feedthrough is preferably at the same time designed as a detachable connection to which an optical fiber cable 16 can be connected. In an advantageous embodiment, the optical waveguide 10 and the optical waveguide of the optical fiber cable 16 consist of a polymeric optical fiber material, preferably polymethacrylic acid methyl ester PMMA. The light guide cable 16 is connected via a fiber coupler 18 to a light source 20 and a light receiver 22 . In a preferred embodiment, the light-conducting parts of the fiber coupler 18 likewise consist of a polymer. An electronic monitoring device 19 is provided to control the light source 20 and to evaluate the signals registered at the light receiver 22 .

The light emitted by the light source 22 to the free end 12 of the optical waveguide 10 is partially totally reflected there and returns to the light receiver 22 via the fiber coupler 18 . The signal measured at the light receiver 22 depends both on the refractive index of the medium surrounding the free end 12 and on the surface shape of the free end 12 . Within the period in which a drop 82 contacts this free end 12 , the signal is smaller than during the period in which the free end 12 is not surrounded by infusion liquid 2 .

According to FIG. 2, the free end 12 of the optical waveguide 10, the shape of a body of revolution about the symmetry axis 50 of the optical waveguide 10, the envelope 52 has a smooth curve in the region of their intersection point with the symmetry axis 50. In a preferred embodiment, the height h of the rotary body is greater than the radius r of the light waveguide 10 . This measure ensures that the geometric shape of the free end 12 which is relevant for the reflection properties is approximately the same in the dry state and in the state wetted with a thin liquid film which results after the drop has been detached from the free end 12 .

The electronic device according to FIG. 3 for monitoring the drip frequency contains a pulse generator 28 which controls the light source 20 via an electronic switch. The light pulses emitted by the light source 20 partially return to the light receiver 22 , which is connected to a Schmitt trigger 26 via a DC voltage decoupling member 24 . The pulses at the output of the Schmitt trigger 26 , which are triggered when the AC component of the signal measured at the light receiver 22 falls below a predetermined threshold value, are fed to a coincidence stage 30 together with the output signals of the pulse generator 28 . The coincidence level 30 is followed by a retriggerable monoflop 32 which provides an output signal which indicates whether the free end is surrounded by infusion liquid or not. The mono flop 32 is connected to a pulse shaper 34 , which, for example, produces a reset pulse for a counter 36 from the flank of the output signal of the monoflop 32 , which corresponds to the detachment of a drop. An adjustable reference oscillator 38 , which specifies the target drip frequency, supplies a clock signal that increments the counter 36 . In a preferred embodiment, a signal is generated in a flip-flop 40 when the counter overflows. In this case the drip frequency is too low. A signal is generated in a flip-flop 42 if the droplet detachment occurs, for example, before half the counting range is reached. This signal corresponds to a drip frequency that is too high. Both a visual and an acoustic alarm can be triggered in a display unit 44 connected to the outputs of the flip-flops 40 , 42 if the drip frequency is too high or too low.

Claims (6)

1. Device for the optical monitoring of the drip frequency in the drop chamber ( 6 ) of an infusion device, characterized by the following features:

• a) In the drop chamber ( 6 ) is an optical fiber ( 10 ) with its free end ( 12 ) below the outlet opening ( 80 ) from a drop former ( 8 ) is arranged,
• b) the optical waveguide ( 10 ) is by means of an optical feedthrough ( 14 ) through the housing of the drop chamber ( 6 ) with an optical fiber cable ( 16 ) via a fiber coupler ( 18 ) both with a light source ( 20 ) and with a light receiver ( 22 ) optically linked,
• c) the light receiver ( 22 ) and the light source ( 20 ) are linked to an electronic device ( 19 ) for monitoring the drip frequency.

2. Device according to claim 1, characterized in that both the light guide the parts of the fiber coupler ( 18 ), and the light waveguide ( 10 ) and the optical waveguide of the light conductor cable ( 16 ) made of a polymeric material be. 3. Apparatus according to claim 1 or 2, marked by a rotary body with a curved envelope ( 52 ) designed free end ( 12 ) of the optical waveguide ( 10 ), the height ( h ) of which is greater than the radius of the optical waveguide ( 10 ). 4. Device according to one of claims 1 to 3, characterized by an optical bushing designed as a detachable optical connection ( 14 ). 5. Device according to one of claims 1 to 4, characterized in that a pulse generator ( 28 ) is provided for controlling the light source ( 20 ) and that the light receiver ( 22 ) via a DC decoupler ( 24 ) with a Schmitt trigger ( 26th ) connected is. 6. The device according to claim 5, characterized in that the output of the Schmitt trigger ( 26 ) and an output of the pulse generator ( 28 ) are connected to a coincidence stage ( 36 ), the output of which via a monoflop ( 32 ) and a pulse shaper ( 34 ) is linked to the reset input of a counter ( 36 ), to the counter input of which the pulse output of an adjustable reference oscillator ( 38 ) is connected.