DE2823670C2 - Device for measuring the pressure of a flowing medium - Google Patents

Abstract

The invention relates to a method and a device for reducing the quantization error. When the class D output stage is digitally controlled with a clock frequency specified by the crystal (42), a pulse is generated at the output of the OR element (41) with the aid of the memory (45), the multiplexer (43) and the counter (40) which, with the help of the D multiplexer (44), reaches the push-pull transistors (T ↓ 1 and T ↓ 2) of the push-pull output stage that act as switches. Within a control period (a), a coarse and fine determination of the final current value (i ↓ L) is carried out by closing the switches (T ↓ 1 or T ↓ 2) twice during the time periods (b and d). The invention can be used in television or data display devices.

Description

The invention relates to a device for measuring the pressure of a flowing medium according to the preamble of claim 1.

In medical practice, e.g. B. in hemodialysis, operations on the heart or the lungs, etc., the patient's blood often has to go outside the body through what is known as an extracorporeal blood circulation system be guided. In order to reduce the risk of infection as much as possible during such interventions the blood-carrying parts are used only once. Doing this can turn out to be a cumbersome, costly one and not one hundred percent reliable cleaning and sterilization of these parts of an extracorporeal ! in the circulatory system. When measuring blood pressure within an extracorporeal blood circuit therefore, the pressure transducers are not allowed to come into contact with the blood. This is achieved by separating the transducer from the blood with a column of air (air duct).

This coupling can be done in two ways:

Either a so-called drip chamber or a T-piece coupling is used. The drip chamber is Usually a cylindrical plastic container approx. 10 cm long and approx. 20-30 cm »large, which is placed in the hose line integrated, is. At the top is the blood supply and the air line for the pressure transducer, at the bottom is the blood outlet. The drip chamber is usually half full with blood. Mirror all pressure changes is reflected in the blood level because the trapped air is easily compressible.

Such a measuring arrangement is nowadays used as standard. She still knows a few serious disadvantages, which can be summarized as follows:

a) As already mentioned, the air is slightly compressible

3 ⁴

bar, which leads to considerable fluctuations in the blood level - the formation of clots is encouraged,

gen Sen can. These fluctuations can be used for the DE-OS 23 15 049 shows a device for Mcs-

You have that the blood either up into the air.

Lehing shoots up or and *, cr & cils the level of the system flowing blood. The known device diirl .IWDkUdIiBlJIfI into the drainage cinec. ι know a line * piece M ^ / ™ Nahrungsmittel * ™ «™

sucks. For this reason, one verxichict also and behind the partition in the pipe section wall

mostly on this application a “relatively cinfu- formed bores”. in e.ne the management

chcn T-piece, because with him because of the small siück dichi enclosing chamber with ctastisencn

Volume, the risk of air being sucked in, pretty much open up to chamber walls. The change in pressure «! _{high is} ίο caused chamber wall movements

b) Because of the effects described in (a) it is also scanned and used to control the amount of blood flow The blood-carrying hoses were drawn in with great effort. Is disadvantageous. that the well-known fore-blood or isotonic solution to fill without the device generating large flow turbulence and a Air bubbles get into the line. Has a number of dead tears. This means that d.e

c) A T-piece connection still has the disadvantage. 15 Danger of increased hemolysis and blood stagnating in the side arm (no direct clots are formed. Pressure changes "tertiary flow or liquid wedge exchange), so that the entire chamber wall spreads, whereby the risk of clot formation arises known measuring device is quite insensitive. in the resulting clots can either enter the blood circulation or block the side arm in a device of the type mentioned and prevent a pressure measurement Disadvantages a to g

d) The high compressibility of air does not occur and that in particular the cut-off frequency of the pressure transducer to be measured greatly reduces. Medium laminar without interference at the measuring point

e) There is an interface between air and blood and a high level of measurement accuracy is achieved, bound the for increased hemolysis (destruction 25 In addition, the device should be an inexpensive manufacturer red blood cells) of the blood. and be easily interchangeable.

0 The blood flow cannot unhindered the measurement happen. The consequence of this is that the species mentioned in the code of the the turbulence form, the features specified for increased haemo- claim 1 solved. Ivse lead or stagnation points occur in 30 Advantageous and expedient further training of the which the formation of clots is favored, the solution to the problem according to the invention is

g) The rather large volume of a drip chamber stated.

increases the volume of the extracorporeal circu- Particularly advantageous. that the medium at

Ling blood b-pregnantly flowing through the according to the invention trained

ling blood D.tracnincn. ^ Measuring device not affected by the measuring process itself

From US-PS 34 13 853 a device is known to interfere, because through the pressure-dependent control ei-measurement of the pressure of blood. This Vorrich- ne practically unchanged Wandungsgeornetne the processing has a line section in which a cylindrical - line is secured, so that unobstructed laminar see membrane is disposed. which is guaranteed by an annular flow. This also surrounds the counter chamber. in which a liquid 40 avoids thrombus formation. Located by the formation of a hydraulic clutch. Using the compensation method and through the annular chamber, a nozzle is connected, in which avoidance of any energetic feedback from which another plane membrane is arranged, which is a very precise control via a measuring device and a rod connected to a strain gauge enables pressure measurement. As a result of the pressure changes according to the invention, the membrane undergoes practically no burn-out cylinders and in the form of volumetric deflections, so that it is hardly subjected to mechanical stress, changes in the pressure of a hose element are carried out by the entire membrane the further effect of the planar membrane by means of the hydraulic parts of the measuring device according to the invention is not transformed. Since a change in pressure is subject to special requirements. The device according to the invention, which is inventively applied to the entire membrane cylinder, can therefore be produced inexpensively, the known measuring device is correspondingly constructed and insensitive as a component of a disposable one. Due to the hydraulic coupling, the hose cutlery (disposable item), as it is e.g. B. in the known device structurally quite expensive. The hemodialysis is used, used, blood-carrying parts of the measuring device do not. As already mentioned above, the present disposable article is used. Which means that they have to be cleaned regularly. It is also disadvantageous that one which is known per se from DE-AS 2 76 931. This temperature drift as a result of thermal expansion of the publication relates to a special device for the enclosed liquid of the hydraulic coupling force measurement, in which a diaphragm creates a pressure space between the two Diaphragms additionally compensate for dividing into two chambers, which must be pressurized with different levels. By increasing the pressure, the eo ken arches. The membrane is connected to a cylindrical membrane to the outside, so that in the blood rod, one end of which is formed by an outward curvature from a conduit leading away from it, which is stressed and the other end of which is connected to a coil through which even at low flow velocities, which is displaceably arranged in an annular gap of an elec- tromagnetic laminar flow, that is to say a flow without disturbance magnets. The electrical stanchions no longer in the region of the measuring point magnet realizable 65 is from the output signals of the displacement probe This is particularly disadvantageous because control of such, so that the force to be measured, which form over points turbulence for enhanced hemo- the membrane is transferred, run through a lysis of the same size or form stagnation points in which the electromagnetic electromagnetic force acting in the opposite direction

table generated force is compensated. A Hall generator is arranged in the magnetic circuit, the operating parameters of which are used to measure the force.

The invention is to be explained in more detail below with reference to the drawing. It shows

F i g. 1 the measuring device according to the invention in a schematic representation and

2 shows a block diagram of the measuring device according to

The measuring device shown in the drawing has an in the flow path of a medium (blood) insertable line piece 1 and a compensation and measuring unit 2, their circuitry Part in FIG. 2 is shown. Hose feed lines of the extracorporeal (5 Called the circulatory system. The Lehungssiück ί has a diaphragm which can be acted upon by the pressure to be measured and which is connected to a displaceable element 14 is connected in the form of a rod, the pressure-dependent displacement of which is measured. The membrane 5 is a wall part formed integrally in a plastic pipe section which forms part of the line section 1 low wall thickness. The membrane is flat.

A small iron disk 6 is glued to the membrane 5. This iron disk forms the counterpart a magnetic coupling, the second part of which consists of a permanent magnet 7. This second part of the Coupling, i.e. the permanent magnet 7, is part of the compensation and measuring unit 2. The compensation and measuring unit 2 has a housing 24 in which a recess 8 serves as an abutment for the line piece 1 is formed, whereby a mechanical relief against external forces such. B. Train on the hose feed lines 4 is reached.

The magnetic coupling consisting of the iron disk 6 and the permanent magnet 7 enables play-free Force transmission between the line piece 1 and the compensation and measuring unit 2.

The compensation and measuring unit has an electromagnet 9 and a travel sensor 10. The electromagnet 9 is made up of two cylindrical coils 11a. 11 b , which are embedded in an iron yoke 12. The iron yoke 12 has a longitudinal bore around which the two coils 11a and 116 are arranged next to one another, the interior of the coil being partially filled by the iron yoke 12.

In the interior of the coils 11a and Mb, which is not filled by the iron yoke 12, an armature 13 is arranged, which partially protrudes into the bside coils. The armature 13 is connected to the magnetic coupling 6, 7 on one side and to a small cylinder 15 on the other side with the aid of non-magnetic rods 14. The rods 14 are fixed in a suspension 16, which can consist of a leaf spring, for example. The suspension 16 fixes the rods 14 in the radial direction and forms an elastic resistance in the axial direction. The more compliant the suspension 16 is in the axial direction, the lower the cut-off frequency of the measuring device. The less elastic the suspension 16 is in the axial direction, the greater the resolution must have the displacement sensor 10 in order to achieve the same measurement sensitivity as with a more elastic suspension. The suspension 16 is practically a smooth parallel guidance of the arrangement of the permanent magnet 7, the rods 14, the armature 13 and the cylinder 15. The iron yoke 12 and the suspension 16 are fixed mi! the housing 24 connected. The travel sensor 10 can be an optical sensor as shown. It has a block 17 which is firmly connected to the housing 24. Two bores 19 arranged perpendicular to the cylinder 15 and aligned with one another are formed in the block. In these holes

19 are opposite to each other a photo receiver

20 and an infrared heater 21 are arranged. The radiation strength of the infrared heater can also be monitored by a further photo receiver serving as a reference. Of course, you can also work with visible light or UV radiation. Inductive or capacitive displacement sensors can also be used. In block 17 a further bore 18 running transversely to the bores 19 is also arranged, in which the cylinder 15 is arranged in such a way that it screens out a more or less large part of the light rays by displacement depending on the extent of the displacement.

The F i g. 2 shows a block diagram of the measuring device, which forms a closed control loop. This closed control loop is formed schematically one after the other by the elastic suspension 16, the displacement sensor 10, a summation point A. a controller 23, the electromagnet 9 and a summation point B. The membrane 5, the signal K _{t of} which is fed to the summation point B , and a zero-point adjustment device 22, the signal Un of which is fed to the summation point A, are located outside this control loop. A pressure ρ in the line piece 1 acts on the membrane 5 and thus exerts a force K \ on the armature 13 held by the elastic suspension 16. The electromagnet counteracts the force K \ with a force K ₂ . The difference between these forces K, and K ₂ causes a shift χ of the armature 13 and thus of the cylinder 15 in the displacement sensor 10. The shift χ is converted into a voltage U , from which the voltage Uo is subtracted, which is used by the zero point adjustment device 22 is generated.

The voltage Uo is used to determine the zero point position. The difference signal U _x - Uo is fed to the controller 23, with the output signal voltage U _{p of} which the electromagnet 9 is fed. The regulator 23 changes the voltage U _p such that its input voltage U _x _ Ij _{0 to} M _U H u / im. ie so that the armature 13 assumes its original position again. In this state, the forces K \ and K _{2 are} equal, and the voltage U ₁ is therefore directly proportional to the pressure ρ.

The direct proportionality can be explained as follows: It is well known that the force K that exerts the magnetic field of the coils 11a and HZj on the armature 13; exerts is proportional to the square of the coil currents / 1 and j I ₂ (see equation G ₁₎ and thus also of the tung Rieh- \ in which they flow through the coils, inde- j gig. The effect of this magnetic force K consists of | in that it tries to reduce the air gap in the magnetic circuit f formed between the armature 13 and the iron yoke j 12. In order to achieve a linear dependency, a constant current k is sent through the two coils 11a and 116, the one! Control current / is superimposed (see equation G ₂ ). I.

K ~

K- (I _n + l) \ (h-ip (C

The forces K generated by the magnetic field of the! Coils 11 ;; and! (^ are subject to an inf linear super positional excitement, so that for the rcsül- i

animal force Kz is given the following relationship:
K ₂ ~ (k + I) ² - (Io - I) ² = 2 / o /

Although the magnetic forces are independent of the direction of the current, it makes sense to choose them in such a way that the magnetic fluxes Φ \ and 4h, which flow through the part of the iron yoke 12 that is located between the coils, are subtracted at the same time. In this way, the radial forces that act on the armature 13 are correspondingly smaller.

If a pressure (or negative pressure) ρ occurs in the hose feed line 4, the membrane 5 and with it the entire arrangement consisting of the permanent magnet 7, the armature S3, the rods 14 and the cylinder 15 are displaced. This deflection χ is scanned with the displacement sensor ICi and converted into a voltage U _p . The voltage proportional to the deviation from the equilibrium position is fed to the controller 23. At the output of the controller 23, the voltage U _{n is set in} such a way that the electromagnet 9 just compensates for the compressive force on the membrane 5 and brings the entire measuring system back into its original position of equilibrium. The voltage U _p is then the desired output signal.

The line piece 1 can be manufactured as an injection molded part and consist of plastic. The membrane 5 can consist of the same plastic as the line piece 1. In a preferred embodiment, this membrane is about 30 mm ² and 0.1 to 03 mm thick. In a practical embodiment of the measuring device, the distance between iron yoke 12 and armature 13 both within the two coils 11.7 and 11 and between the coils is approximately 0.5 mm.

For this purpose 2 sheets of drawings

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15th

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Claims (12)

Patent claims: ί. Device for measuring the pressure of a flowing medium, in particular blood, in one extracorporeal circulatory system, with a line piece that can be inserted into the flow path of the medium, which has a diaphragm which can be acted upon by the pressure to be measured and which is connected to a displaceable Element is connected, the pressure-dependent displacement of which is measured, thereby characterized in that the membrane (5) forms only part of the jacket of the line piece and that the displacement of the element (14) caused by a lowering of the membrane (5) by a travel sensor (10) is scanned, the output signal of which is an electromagnetic one, which is dependent on the degree of displacement actuatable control element (13) which is firmly connected to the displaceable element (14), controls so that the displacement of the element and the deflection on the displaceable element (14) the membrane (5) compensating counterforce is exerted. 2. Apparatus according to claim 1, characterized in that the membrane (5) in a plastic pipe section, which forms part of the line piece, integrally formed wall part less Wall thickness is. 3. Apparatus according to claim 1 or 2, characterized in that the membrane or the wall part is planar and has an area of about .30 mm ² with a wall thickness of 0.1 to 0.3 mm. 4. Apparatus according to claim 1, characterized in that that the actuator (13) is the armature of a "Electromagnet (9), the stationary coil (11 a, 11 b) of which is fed by the output signals of the displacement sensor (10). 5. Device according to one of the preceding 'claims, characterized in that the membrane (5) is connected to the displaceable element (14) via a magnetic coupling (6, 7). 6. Apparatus according to claim 5, characterized in that the magnetic coupling consists of a fixed to the membrane (5) connected iron disc (6) and a fixed to the movable element (14) connected permanent magnet (7) consists. 7. Device according to one of claims 4 to 6, characterized in that the electromagnet (9) has an iron yoke (12) with a bore around which two ring-shaped coils embedded in the iron yoke are arranged coaxially next to one another, and in which the armature (13) is arranged between the two coils so that it partially protrudes into both, and that the armature (13) is connected to the membrane (5) via the magnetic coupling (6, 7). 8. Apparatus according to claim 5 or 6, characterized in that the displacement sensor (10) has a block with a to the axis of the coils (11a, Wb) coaxial bore (19), further a with the armature (13) coupled, in the bore (18) displaceably arranged body (15) and a light barrier (20,21) arranged perpendicular to the direction of movement of the body (15), the beam path of which is more or less blocked by the body (15) according to the deflection of the membrane (5). 9. Apparatus according to claim 8, characterized in that the armature (13) with the magnetic Coupling (6, 7) on the one hand and the body (15) on the other hand connected via the displaceable element (14) is mounted by means of suspensions (16) which can be deflected in the longitudinal direction of the element (14). 10. The device according to claim 9, characterized in that the displaceable element (14) consists of non-magnetic rods. 11. Device according to one of the preceding claims, characterized in that in a controlled system (A9, 23) a comparison circuit (A) for comparing the output signal of a zero-point adjustment circuit (22) is provided of displacement probe (10) having a one divisible reference signal, that the signal output of the comparison circuit (A) is connected to the signal input of a controller (23) contained in the controlled system ( A 9, 23). whose output signals the coils (11a, Lindes electromagnet (9) controls so that the input signal of the controller (23) disappears. 12. The device according to claim 11, characterized in that the controller (23) feeds one coil (Wa) with a current h = / o + I and the other coil (Wb) with a current h = h - /, wherein / o is a constant current and / the control current corresponding to the pressure to be measured.