DE2937195B2 - Blood coagulometer - Google Patents

Description

The invention relates to a blood coagulometer according to the preamble of claim 1.
In a known blood coagulometer of the generic type (DE-OS 26 31 950) there is a ball, possibly also a steel ball, in the measuring tube, which is held in an inclined position and driven in rotation, the ball raceway in the bottom area of the measuring tube over the inclined position of the measuring tube is formed on the one hand at the bottom of the measuring tube itself, on the other hand also by the lower measuring tube wall area. The ball is rotated by the rotation of the measuring tube

ίο Due to the inclination, it is also on one given place. If the fibrin threads begin to form at the start of coagulation, it happens due to the adhesion of the fibrin threads to the glass ball as well as to the bottom and wall area of the Measuring tube to ensure that the ball is carried along by the measuring tube when it rotates. It is coming to a change in location of the ball, which is either registered there by the operator with the eye is, whereupon a timer or a comparable recording device is operated. It is there also already planned to use a steel ball and a magnetic sensor on the from to arrange the ball in the driving phase described pathway. Despite this configuration is an exact automatic measurement of the clotting time with such a blood coagulometer does not make sense possible, especially because the entrainment movement of the ball is relatively uncertain and because the ball is very fast towards the middle of the bottom of the measuring tube under hers

jo own weight can evade, which often results in only a very slight displacement movement of the Ball that cannot be correctly registered automatically. This is all the more true as the ball in its normal position through the touch

ΐϊ both with the bottom of the measuring tube and with the lower area of the wall of the measuring tube, as a result of this relatively strong contact, has a tendency to premature entrainment as well as a tendency to tumble and rocking movements. The magnetic sensor provided there as an alternative makes it possible to work not only with light but also with dark plasma samples and whole blood samples. A magnetic sensor that enables the very precise measurement and control pulse triggering required here is not shown there.

The present invention is based on the object of providing a coagulometer of the generic type to create the exact and reliable detection of the coagulation time with a simple structural design enables.

The solution according to the invention results from the characterizing part of claim 1.

The design there has the effect that at the start of coagulation not only a fibrin thread framework is formed between the ball in the area of its ball track, but also between the ball and the corresponding area of the measuring tube wall and, in particular, the opposite one as well forms between the ball and the corresponding area of the limiting pin. This prevented the limiting pin also ensures that the ball is taken along by the rotating Measuring tube can move under its own weight towards the center of the tube bottom. It comes up here particularly safe and precise way to take the ball with you when the coagulation starts, and the ball also runs through a precisely defined path in the take-along phase in such a way that this exact change in position

tion can also be automatically registered automatically by the sensor accordingly. In the Phase in which the ball from the rotating measuring tube is not yet taken along, and because of the very little contact with the measuring tube, none Tendency to be picked up too early: or to rocking and tumbling movements.

Preferred configurations are characterized in the subclaims.

The use of a specially designed channel according to dependent claim 2 causes the ball in first part of the measuring phase practically always only one has punctiform contact with the measuring tube, which contributes in particular to untimely entrainment of the ball or tumbling and rocking movements of the balls with great certainty.

After the design of the measuring tube is now the point in time of the ball entrainment is made possible very precisely and the ball is given a precisely defined driving distance, identifies dependent claim 6 a sensor design that is adapted to this exactness and also works correspondingly precisely, because such a magnetic sensor has no hysteresis behavior, i.e. as a linear transducer is to be seen

One embodiment of a blood coagulometer is described in more detail below with reference to the drawing. It shows

F i g. 1 is a plan view of a Meßröhrch on the Blood coagulometer,

2 shows a section along the line II-II of FIG. 1 with representations of the measuring tube in his inclined functional position,

F i g. 3 the circuit diagram of the magnetic sensor and the associated control circuit of the blood coagulometer.

That in Jen F i g. 1 and 2 shown measuring tube 1 of the coagulometer has a substantially cylindrical side wall 2, which tapers slightly upwards in its material thickness and which is at right angles into the Bottom 3 of the measuring tube passes. The base 3 is centered on the central longitudinal axis of the tube a conically tapering upward boundary pin 4 in front. Furthermore, the bottom 3 defines a Ball track for a steel ball 5 to be arranged in the measuring tube (see FIG. 2). This ball track is defined by a channel 6 which is formed in the bottom 3 and which has a radius of curvature that is slightly larger than the radius of the ball 5. This configuration has the effect that the ball 5 is practically only with point contact in the channel 6.

As shown in FIGS. 1 and 2, the limiting pin 4 is thereby on its outer jacket corrugated that it has several, spaced apart, parallel to the longitudinal axis of the measuring tube, small Web 7 is provided. The side wall 2 of the measuring tube is also in its lower part with the ball 5 cooperating area corrugated, also in the form of some spaced apart, to Longitudinal tube axis of parallel, small webs 8. The webs 7 and 8 protrude only so far that they at least cannot have any contact with the ball 5 located in the channel 6 in the normal phase of operation. The arrangement of the channel 6, its dimensions and the dimensions of the ball and the Diniensioning of the webs is such that the ball 5 in this normal phase only gei ingein Distance from the respective affected areas of the webs 7 and 8 is.

The design is such that, in contrast to the side wall 2, the webs Ά of this side wall run into the channel 6 with a radius of curvature corresponding to the radius of curvature of the channel itself. The webs 7 and 8 are designed so that they taper slightly upwards, both in terms of their height and their width.

The coagulometer contains a dry thermostat (not shown) in which the measuring tube is in a slightly inclined position of approx. 10 ^c - this inclined position is shown in FIG. 2 shown - is rotatably mounted. The measuring tube 1 is set in slow rotation about its longitudinal axis by a rotary drive, not shown. Due to the inclined position of the measuring tube, the steel ball 5 is held at a predetermined point relative to the measuring tube 1 and it is set in rotation by the point contact with the rotating measuring tube itself, but otherwise retains its specified spatial position due to its own weight. When the coagulation occurs, in the narrow spaces between the steel ball 5 on the one hand and the free partial areas of the channel 6 and in particular the side wall 2 and the delimiting pin 4 and here again in particular between the affected web areas 7 and 8, an immediately formed through the webs 7 and 8 on the other hand particularly well anchored fibrin thread framework, which ensures that the steel ball 5 is carried along safely and precisely in terms of time

j? Measuring tube 1 leads. The steel ball 5 now follows the rotary movement of the measuring tube t and thereby leaves the initially predetermined position. This in Each way exactly defined change in position is in the illustrated embodiment by an adjacent to the outer jacket of the measuring tube 1, in the area of the steel ball 5 in the Entrainment phase traversed path track arranged magnetic sensor registers a control pulse triggers a registration mechanism for the coagulation time that was set in motion when the coagulation batch was entered to pop.

The magnetic sensor 9 used in the illustrated embodiment, together with its control circuit, is shown in FIG F i g. 3 shows the magnetic sensor used

so has an integrated Hall system 10 and is designed for an induction change in an oroportiona-Ie To convert voltage change, with a positive increase in the output voltage with increasing induction he follows. Such a magnetic sensor with Hall system has no hysteresis behavior, so it is to be regarded as a linear converter. On the back of the sensor chip is a permanent magnet (not shown) provided, which generates an inductive bias, which ensures that the change in One such method is to achieve induction simply by approaching a magnetic material The change in induction extends lengthways through the sensor chip as the one on the back Permanent magnet and the passing magnetic

b5 material on the front the causes of the magnetic flux are. Via a passive y? C low-pass filter 11, which suppresses interference is used, the signal emitted by the sensor 9 arrives

capacitive to a first operational amplifier 12, specifically to its non-inverting input. As a special feature, this first operational amplifier is wired in such a way that its inverting input receives part of the output voltage of the operational amplifier via a resistor-resistor combination, one resistor being controllable and at the same time bridged by a capacitance. The amplification ratio of the operational amplifier 12 results from the set ratio of the two resistors. The bridging capacitance C automatically reduces this set ratio and thus the gain as the frequency rises. As a result, signals with a high rate of voltage change, which are a frequent cause of interference, are completely counter-coupled and have no possibility of influencing the measurement.

The highly amplified signal obtained in this way at the output of the operational amplifier 12 is a second operational amplifier 13 is supplied, which operates as a voltage comparator with hysteresis. That Hysteresis behavior ensures that there is no continuous switching. The sound is like that formed that the inverting input of the operational amplifier 13 in Art a voltage divider, for example, half the voltage is specified in such a way that the operational amplifier when it exceeds half the supply voltage as provided by the first operational amplifier 12 to the non-inverting input of the opera jo tion amplifier 13 is given, emits a pulse that is used as a stop signal for the clotting time measuring Register, for example an electronic stopwatch (not shown), is taken. Of the The course of the triggering is such that the ball 5 in the entrainment phase first sew the sensor 9 and then passes it, so that there is a half-wave shape of the signal. Through the described The arrangement and configuration of the second operational amplifier 13 is exactly the point, on the rising edge of such a half-wave, set at which the stop signal for the electronic Stopwatch is delivered.

In order to also switch off the influences of the mains supply and to keep the operating points once set stable naiten, the described control circuit is appropriate including the sensor fed via a voltage regulator. At the same time, a temperature-stabilized Differential voltage source the reference voltage required to set the offset voltage of the sensor.

In the embodiment described above, in a structurally particularly simple manner Steel ball 5 in the first phase of the measurement by gravity in connection with the inclination of the Measuring tube held in place. As a modification of this, in special cases it could be in vertical position The measuring tube also holds the ball with a small holding magnet of a predetermined force be held at the predetermined location.

For this purpose 3 sheets of drawings

Claims (9)

Patent claims: 1. Slut coagulator, with a rotating drive Measuring tube and one in its bottom area in a track provided there Ball held at a predetermined position and rotatably movable from the wall of the measuring tube, which can be carried along by the measuring tube wall at the time of fibrin fiber formation, as well as with a sensor that triggers a control pulse, which is attached to the ball in the driving phase described pathway is arranged. characterized in that in the measuring tube a centrally from the bottom (3) projecting limiting pin (4) provided and such the Ball track (6) assigned and the latter is designed so that the ball (5) in a small Distance both from the limiting pin (4) and from the measuring tube wall (2). 2. blood coagulometer according to claim 1, characterized characterized in that the ball track is formed by a channel (6) formed in the bottom of the measuring tube (3) is defined whose radius of curvature is slightly larger than the radius of curvature of the ball (5) 3. blood coagulometer according to claim 1, characterized in that the limiting pin (4) and the measuring tube wall (2) are corrugated in their spherical areas. 4. blood coagulometer according to claim 3, characterized in that the corrugation by small, spaced apart and parallel to the measuring tube longitudinal axis webs (7,8) is formed. 5. blood coagulometer according to claim 4, characterized in that the wall on the measuring tube (2) provided webs (3) with a radius corresponding to the channel radius in the channel (6) come in. 6. blood coagulometer according to claim 1, characterized in that the sensor for the off ferromagnetic material existing ball (5) a magnetic sensor (9) with an integrated Hall system (10) is. 7. blood coagulometer according to claim 6, characterized in that the sensor (9) controls is linked to an operational amplifier (12) whose non-inverting input is applied, wherein the inverting input of the operational amplifier (12) with part of its Output voltage is connected via two resistors, one of which is adjustable, which the latter is bridged by a capacity. 8. blood coagulometer according to claim 7, characterized in that between the output of the magnetic sensor (9) and the non-inverting input of the operational amplifier (12) passive /? C low pass (ll) is switched on. 9. blood coagulometer according to claim 7, characterized in that behind the first operational amplifier (12) a second operational amplifier (13) is provided, which acts as a voltage comparator is wired with hysteresis.