DE3923079A1 - Measuring level of electrically conducting liquid - has measuring of infusion liquid or blood from change in capacitance of electrodes in measurement liquid - Google Patents

Abstract

The level of an electrically conducting liquid is determined from the capacitance change of a capacitor contg. two electordes. The wall of the container holding the liquid is a dielectric which determines the capacitance. The electrically conducting liquid (15) forms one of the electrodes whose change in area is evaluated. The other electrode (5) is mounted outside the container and extends over the entire possible fill height. USE/ADVANTAGE - For accurate simple measurement of the level of infusion liquid and blood in medical applications, esp. in an infusion spray pump drop chamber and esp. of small quantities.

Description

The invention relates to a method for measuring the Level of in medical technology usable electrically conductive liquids, especially infusion fluids and blood, in a container, especially in a syringe Infusion syringe pump or a drip chamber, at which is the change in capacitance of a two electrodes having capacitor is detected.

The invention also relates to a device for Perform this procedure with one in one Container located electrically conductive Liquid and a having two electrodes Capacitor and one connected to it Evaluation unit.

The measurement of level heights is known and will used wherever there is an exact Detection of filling quantities arrives.

A special area of application is End of delivery detection for syringe infusion pumps.

Syringe pumps are used in the clinical field and in medical research used to Patients have smaller amounts of fluid over one to apply for a longer period. In particular the syringe pumps become continuous and regulated infusion of highly effective drugs used.

Since syringes have a limited volume, the Syringe to be changed from time to time  guaranteeing continuous drug delivery. Remaining quantities of the drug remain in the Syringe. Especially when using Morphine not only brings this procedure elevated Costs, but also logistical problems, since the consumption of morphine is quantified must be discarded and residual quantities not simply thrown away can be.

An attempt was therefore made to create facilities that can safely recognize when a syringe is empty can. These include e.g. Position sensors that the Detect the position of the syringe plunger.

From US-PS 37 01 345 is one Infusion syringe pump known to be a Position control system that a Feedback voltage signal used that the Syringe plunger position is assigned. This Feedback signal is generated by a mechanical driven potentiometer generated by the Drive motor via an additional gear unit is put into operation.

Infusion syringe pumps are also known at which is the driving part of the piston with one Absolute displacement sensor is coupled. As A linear potentiometer, an inductive, capacitive or magnetic positioning element used. But there Syringe has tolerances, this can Position detector the end position of the piston in the cylinder only recognize with about 1-3 mm tolerance.  

Another known way to determine the end position of the Detecting pistons consists in detecting the Propulsive force. If the piston is at the end of the cylinder, as a rule, the force does not increase suddenly but slowly, because the syringe plunger is one has compressible rubber seal. In both mentioned cases there is a temporal Delay of the signal compared to the actual one End of infusion.

If you also take into account that with the usual 50 ml syringe infusions at rates of typically 3 ml per hour and less be applied, with 1 ml about one Corresponds to a piston travel distance of 1 ml understandable that there are delays in the Alarms come from 30 minutes to 2 hours can. This is at least when using Medications are therefore not permitted.

Another area of application is Level detection of blood levels in drip chambers, e.g. in the extracorporeal circulation one Hemodialysis device are arranged. A Level detection can, for example, with Photoelectric barriers are made, but with what discrete fill levels can be detected. The measurement using ultrasonic detectors is technically extremely complex.

It is therefore an object of the present invention To provide methods and an apparatus with in the medical field the level of electrically conductive liquids, namely Infusion fluids and blood especially smaller  Quantities, precisely and easily determined can be.

This task is accomplished with a method according to the Characteristic of claim 1 solved.

With capacitive measuring technology, the effect exploited that the capacity of a capacitor by its area, the distance between the areas and the Dielectric constant of the dielectric determined becomes. Capacitive sensors are like this constructed that they are changing one of these Detect sizes.

Operation of the well-known capacitive Proximity sensors require, however, that the detecting object a large mass and therefore a large capacity relative to earth potential having. The circuit of the proximity switch is also grounded on one side so that the circuit high frequency is closed over the earth.

Alternatively, reference electrodes can also be attached be so that the high frequency circuit of the To detect reference electrodes Object leads to the sensor electrode.

The application of these procedures is then however difficult if the level is small of liquid to be detected, since the for Available electrode areas are small, which in turn leads to very small capacities that an extremely sensitive and therefore also circuit susceptible to interference is required.  

However, it has surprisingly turned out that the capacitive measuring technology for Level measurement of small amounts of liquid can be used when it is namely the Detection of an electrically conductive Fluid, such as infusion fluids or blood, acts, which then as one of the two electrodes of the Capacitor is used. As capacity-determining dielectric then becomes the Container wall used. In this way, the Measurement on the change in the effective area of the electrically conductive liquid can be reduced including that surface of the liquid understand that is adjacent to the inner wall of the container and facing the outer electrode.

To maximize the effective area of the to get electrically conductive liquid, it is advantageous, the surface of the outer electrode as possible great to choose.

The decrease or increase in the effective area of the electrically conductive liquid is then directly with correlates with the corresponding level.

In the device according to the invention Carrying out this procedure is one Electrode arranged on the outside of the container and spans the entire, possible Level. The electrically conductive liquid forms the second electrode and is over one electrical contact with the evaluation unit connected.  

The outer electrode preferably covers the entire Outer surface of the container, creating a corresponding large effective area of the electrically conductive Liquid is generated.

Preferred uses of this device exist in the end of funding recognition Syringe infusion pumps and in use as Level detector of a drip chamber.

According to a particular embodiment, the Container from a syringe barrel and the electrically conductive liquid from a Infusion fluid. The syringe barrel can for example the syringe barrel one in one Syringe infusion pump can be used syringe. The electrical contact is one on the Syringe cone of the syringe, tubular connector that has a corresponding Has inner cone. The other end of the Connection piece is for receiving a hose educated. The electrical contact can also over the metallic cannula are made.

The outer electrode preferably extends over the entire stroke of the syringe plunger.

According to a further embodiment, the Containers from a drip chamber as in Find hemodialysis devices. The in this case it is an electrically conductive liquid the dialyzed blood. The electrical contact is also designed as a connector that on the Outlet of the drip chamber is plugged on. Since that Blood also in conductive contact with the  Dialysis fluid is available, there is also Possibility of electrical contact in the Arrange the dialysis fluid circuit.

Since the connector with the electrically conductive If liquid comes into contact, it is there preferably from a physiologically tolerable Material that is also electrically conductive is. Suitable materials are conductive Plastics, conductive charcoal and conductive Glass coal.

The evaluation unit to which the connector and the outer electrode is connected either a measuring bridge or a resonance circuit for Evaluation of the change in capacity of the two Electrode formed capacitor. Preferably become RF oscillator circuits for evaluation used. Exemplary embodiments of the Invention are described below with reference to the drawing explained in more detail.

Show it:

Fig. 1 is a schematic representation of the device according to the invention in connection with an infusion syringe;

Figure 2 is a plan view of an infusion syringe pump with the inventive device.

Fig. 3 is a schematic representation of the device according to the invention in connection with a drip chamber.

In Fig. 1, the device according to the invention is shown in connection with an infusion syringe 1 a. A syringe plunger 2 is guided in the syringe barrel 3 . The outer electrode 5 is arranged on the outside of the syringe barrel 3 in the region of the stroke of the syringe plunger 2 .

At the front end, the syringe barrel has a syringe cone 4 , to which the syringe line 7 is usually connected. In the embodiment shown here, a connector 6 a is arranged between the syringe cone 4 and the syringe line 7 , which has an inner cone 25 and can therefore be plugged onto the syringe cone 4 .

This connector 6 a is made of a physiologically compatible conductive material. This connector 6 a is connected to the evaluation unit 10 via an electrical connecting line 8 . The outer electrode 5 is also connected to the evaluation unit 10 via the line 9 . A protective cover can also be provided between the outer electrode 5 and the syringe plunger 3 .

The evaluation unit 10 has an RF oscillator circuit, so that due to the connections of the outer electrode 5 and the connector 6 a, a capacitive high-frequency circuit is closed, the electrode 5 , the wall of the syringe 1 a, the conductive infusion solution 15 , the conductive connector 6 a and the two lines 8 and 9 is formed. The impedance-determining part is the wall of the syringe barrel 3 . All other contributions are comparatively low impedance. The conductive infusion solution 15 forms one electrode of a capacitor and the electrode 5 the other. The capacitance of this capacitor and thus its high-frequency impedance changes during operation with the electrode surface which is formed by the infusion solution 15 , since all other parameters remain constant. If, for example, a high-frequency voltage is therefore applied to the electrode 5 and the connector 6 a, the current in this circuit will decrease as the volume of liquid in the syringe 1 a decreases and will eventually be close to zero when the syringe 1 a is empty. The HF current flowing in this state is due to residual capacities, which can be determined once and included in the evaluation.

In FIG. 2, the plan view is displayed on a syringe infusion pump 20. The syringe pump 20 has a housing 21 , the upper side of which is provided with a holder 22 which partially surrounds the syringe barrel 3 on the circumference. In this trough formed by the holder 22 , the tubular outer electrode 5 is arranged, into which the syringe 1 a is inserted, so that the entire syringe barrel 3 is surrounded by the outer electrode 5 . When inserting the syringe 1 a, the cone engages in the connector 6 a, to which the hose 7 is attached. The evaluation unit, which is connected both to the connector 6 a and to the outer electrode 5 , is an integrated component of the infusion syringe pump 20 and arranged in the housing 21 . The evaluation unit is connected to a position detector 23 arranged on the syringe infusion pump 20 , which then emits a signal when the syringe 1 a is empty.

In Fig. 3, a drip chamber 1 b is shown in section. This drip chamber 1 b is provided with a cap 14 in which three nipples 11 , 12 and 13 are arranged. Over the nipple 12, the dialyzed blood is supplied while the b can escape in the drip chamber 1 air located over the nipple. 13 The nipple 11 serves as a connection to a pressure measuring device. The outer electrode 5 is arranged on the outer wall as a ring or as a partial ring and is connected to the evaluation unit 10 via the line 9 . At the outlet 16 of the drip chamber 1 b, the connector 6 b is attached, which, as in the embodiment of FIG. 1, is made of a physiologically compatible, conductive material. This connector 6 b is also connected to the evaluation unit 10 via the electrical line 8 . At the lower end of the connector 6 b, the hose 7 is attached. With the device according to the invention, the respective fill level of the electrically conductive liquid 15 can be determined exactly at any time, so that corresponding control signals can be given, for example, to the connected hemodialysis device.

The control signals can also be used to by ventilating the liquid level in to regulate the drip chamber.

Claims (11)

1. A method for measuring the level of electrically conductive liquids that can be used in medical technology, in particular infusion liquids and blood, in a container, in particular in a syringe of an infusion syringe pump or a drip chamber, in which the change in capacitance of a capacitor having two electrodes is detected, characterized in that
that the container wall is used as a capacity-determining dielectric and the electrically conductive liquid as one of the two electrodes and
that the change in the area of this one electrode is evaluated. 2. Device for carrying out the method according to claim 1, with an electrically conductive liquid, in particular infusion liquid and blood, located in a container, and a capacitor having two electrodes and with an evaluation unit connected thereto, characterized
that one electrode ( 5 ) is arranged on the outside of the container and extends over the entire possible level, and
that the electrically conductive liquid ( 15 ) forms the second electrode and is connected to the evaluation unit ( 10 ) via an electrical contact. 3. Apparatus according to claim 2, characterized in that the outer electrode ( 5 ) covers the entire outer surface of the container. 4. Apparatus according to claim 2 or 3, characterized in that the container is a syringe cylinder ( 3 ) and that the electrical contact as a on the syringe cone ( 4 ) attachable, tubular connector ( 6 a) with an inner cone ( 25 ) is formed. 5. The device according to claim 4, characterized in that the outer electrode ( 5 ) extends over the entire stroke of the syringe plunger ( 2 ) on the outside of the syringe barrel ( 3 ). 6. The device according to claim 2, characterized in that the container is a drip chamber ( 1 b) of a hemodialysis device and the electrically conductive liquid ( 15 ) dialyzed blood and that the electrical contact as a on the outlet ( 16 ) of the drip chamber ( 1 b ) attachable connector ( 6 b) is formed. 7. Device according to one of claims 2 to 6, characterized in that the connecting piece ( 6 a, 6 b) consists of a conductive plastic. 8. Device according to one of claims 2 to 6, characterized in that the connecting piece ( 6 a, 6 b) consists of a conductive charcoal. 9. Device according to one of claims 2 to 6, characterized in that the connecting piece ( 6 a, 6 b) consists of a conductive glassy carbon. 10. Use of the device according to claim 2 for End of delivery detection for syringe infusion pumps. 11. Use of the device according to claim 2 as Level detector of a drip chamber.