DE4407176A1 - Pressure measurement using fiber optics - Google Patents

Abstract

In a pressure measuring device, in particular for medical pressure measurements, a mechanical pressure sensor is connected to an evaluating electronic system (10) by means of a beam wave guide (3). In order to compensate adulteration of the measurement result by movements and flexions of the beam wave guide (3), a comparison beam wave guide (4) can be moved flexibly together with the beam wave guide (3) and parallel thereto. The light signal of the comparison beam wave guide (4) is uninfluenced by the pressure in the pressure sensor (2) and is delivered as a reference signal to the evaluating electronics system which, by means of the reference signal, compensates changes in the measured value which are caused by movement.

Description

The invention relates to a pressure measuring device, in particular especially for medical pressure measurements, with a me chanic pressure sensor, which uses an optical fiber ter is connected to an evaluation electronics, wherein a light signal is supplied to the optical waveguide and he a measurement signal corresponding to the prevailing pressure to the evaluation electronics.

Such a pressure measuring device is in DE 40 18 998 A1. One of the pressure sensors is too high send pressure exposed membrane arranged whose zen against the optical fiber. The light beam from the optical fiber hits the reflector ting membrane and will correspond in the optical fiber according to the pressure-dependent distance Fiber optic routed to the evaluation electronics.

Such pressure measuring devices have the advantage that they work free of an electrical potential. Of the Pressure sensor is galvanic from the evaluation electronics decoupled.

In medical pressure measurements, for example Strain gauge bridges, piezo crystal transducers ver turns that over wire connections with the evaluator electronics are connected. Electrical Ver connections between the respective sensor and the off value electronics necessary. Such are often undesirable. The electri Avoid cables. However, it should then be in the Sensor provided an electrical power supply his. This would increase the size of the sensor  which is particularly important for medical pressure measurements is part, in which the sensor on or in the patient to be placed.

For pressure measurements, especially in medical technology, the optical fiber must be flexibly movable so that it can be flexibly routed to the relevant measuring point can. It has been found that such movements of the Optical fiber to falsify the measurement result to lead.

The object of the invention is a pressure measuring device to propose of the type mentioned at the outset at the Ver falsifying the measurement result when moving or bending of the optical waveguide, compensate are based.

According to the invention, the above object is for a pressure measurement device of the type mentioned solved by that parallel to the optical fiber a comparison Optical fiber is guided together with this is bendable and movable like the optical fiber Light signal conducts, and that the light signal of the Ver equal optical fiber from the pressure in the pressure sensor un is influenced and as a reference signal of the evaluation tronics is supplied by means of the reference signal movement-related changes in the measured value are compensated.

The optical fiber and the comparative optical waves conductors are the same movement-related disorders subject. The light sig is only in the optical fiber nal influenced by the measured variable. Like a measurement bridge the light signals of the light waves conductor and the comparison optical fiber ten, so that in the end result the measured value is not determined by Be Ver movements or bends of the optical fiber is fake.  

The pressure measuring device does not require galvanic Ver binding between the pressure sensor and the evaluation elec electronics and no active transmitter in the pressure sensor. Of the Pressure sensor is therefore very small buildable, so that it also easily insert into a patient's body parts ren leaves.

Advantageous refinements of the invention result from the subclaims and the following description of embodiments. The drawing shows:

Fig. 1 is a diagram of a pressure measuring device schematically that one works on the principle In terferometers,

Fig. 2 is a circuit diagram of a further embodiment of the pressure measuring device, which operates with phase measurement,

Fig. 3 is a circuit diagram of a pressure measuring device schematically, which operates at a loss measurements,

Fig. 4 is a sectional view of a pressure sensor taken along the line IV-IV of FIG. 5, enlarged,

Fig. 5 is a plan view of the pressure sensor of FIG. 4,

Fig. 6 shows a different type of pressure sensor in section.

The pressure measuring device has an optical fiber arrangement ( 1 ), which comprises a pressure sensor ( 2 ), an optical fiber ( 3 ) and a comparative optical fiber ( 4 ). The mechanical structure of the pressure sensor ( 2 ) is shown in FIGS. 4 and 5. The Lichtwellenlei ter ( 3 ) and the comparative optical waveguide ( 4 ) each have a piece leading to the pressure sensor ( 2 ) and a piece leading away from the pressure sensor ( 2 ). The four pieces lead on the same side in the pressure sensor ( 2 ) (see FIGS. 4, 5).

The comparison optical fiber ( 4 ) and the optical waveguide ( 3 ) are laid in parallel next to each other. They are flexibly movable and run in a common protective tube ( 5 ).

The pressure sensor ( 2 ) has a base body ( 6 ) which carries a pressure-sensitive membrane ( 7 ). When pressure is applied in the direction of arrow (D), the membrane ( 7 ) is deflected. The back ( 8 ) of the membrane ( 7 ) is mirrored. The optical fiber ( 3 ) ends with its two parallel pieces in the pressure sensor ( 2 ) in front of a mirrored deflection surface ( 9 ), which directs the light emerging from the one piece of the optical fiber ( 3 ) onto the mirrored back ( 8 ) of the membrane ( 7 ) Which light leads over the deflecting surface ( 9 ) back into the starting piece of the optical waveguide ( 3 ). Depending on the pressure-dependent deflection of the membrane ( 7 ), the outgoing light is influenced in relation to the incoming light.

The comparison optical fiber ( 4 ) is also guided into the pressure sensor ( 2 ). However, its two parallel pieces are connected there so that they are not influenced by the membrane ( 7 ).

The deflection surface ( 9 ) can, as shown in FIG. 5, be an integral part of the base body ( 6 ). Alternatively, it can also be a separate prism component which is inserted and fastened into the base body ( 6 ) at the specific position. To the steering surface ( 9 ) each extends at an angle of 45 °.

The light guide arrangement ( 1 ) is connected via a connector (not shown in more detail) to an evaluation electronics ( 10 ).

In the evaluation electronics ( 10 ) of FIG. 1, the two optical fibers ( 3 , 4 ) from a laser diode ( 11 ) via a semi-transparent mirror ( 12 ) is supplied with a light signal. In the course of the comparison Lichtwellenlei age ( 4 ), an actuator ( 13 ) is arranged, which is similar in its function of the membrane ( 7 ) of the pressure sensor ( 2 ) and with which the optical length of the comparison optical fiber ( 4 ) accordingly can be adjusted. For example, the actuator ( 13 ) is a motor-adjustable mirror or a magnetostrictively extendable optical fiber.

The light signals of the optical waveguide ( 3 ) and the comparison optical waveguide ( 4 ) are guided to a light receiver ( 15 ) via a semi-transparent mirror ( 14 ). The received signal is amplified in an amplifier ( 16 ) and passed to a controller ( 17 ). The controller ( 17 ) adjusts the actuator ( 13 ) so that the output voltage at the amplifier ( 16 ) becomes a minimum. This is the case when the optical length in the section of the optical waveguide ( 3 ) is equal to the optical length in the section of the comparison optical waveguide ( 4 ). The necessary adjustment of the actuator ( 13 ) is displayed. It represents the pressure measured value. In the measured value, disturbances, for example bending-related disturbances, which affect the two optical waveguides ( 3 , 4 ) in the same way, are not included.

In this device, a corresponding change in length (d4) is set in accordance with the respective pressure-dependent optical length change (d3) in the optical waveguide ( 3 ) in the comparison optical waveguide ( 4 ) and this is displayed.

In the exemplary embodiment according to FIG. 2, the light signal ( 3 , 4 ) via laser diodes ( 11 , 11 ') is UHF-modulated, the frequency (f1) being in the range from, for example, 100 MHz to 1 GHz and approximately 30 kHz in the modulator ( 18 ) can be regulated by a controller ( 19 ). The comparison optical waveguide ( 4 ) is preceded by an optical path ( 20 ) of length lamda / 4 of f1.

Light receiver ( 15 , 15 ') of the evaluation electronics ( 10 ) lead the light signals of the optical fibers ( 3 , 4 ) to a phase detector ( 21 ) which controls the controller ( 19 ). The controller ( 19 ) controls the frequency (f1) so that there is a phase shift of 90 °. The deviation from this is proportional to the pressure-dependent deflection (d3). This can be shown on a display ( 22 ). In this case too, falsifications based on bends in the optical waveguides ( 3 , 4 ) are compensated for in the measurement result.

The transmitter (10) of Fig. 3 operates with a 20 kHz signal generator (23), which is ( '11, 11) are closed via an actuator (24) and an LED driver (25) to IR-diodes is that are coupled to the light guides ( 3 , 4 ). Light receivers ( 15 , 15 ') are connected to electrical amplifiers ( 26 , 26 '), to which, in accordance with the light attenuation in the optical waveguide ( 3 ) with the respective measuring path (d3) and the comparative optical waveguide ( 4 ), the voltages (U1 or U2). The voltages (U1, U2) are from the generator ( 23 ) controlled phase rectifier ( 27 , 27 ') and possibly further amplifiers to a micro-controller ( 28 ). At this, a controller ( 29 ) is connected, which cher controls the actuator ( 24 ) so that the voltage (U2), which is derived from the comparison optical fiber ( 4 ), remains constant. Disturbances of the measurement result, which are based on bending-related damping conditions in the optical fibers ( 3 , 4 ), are regulated from, so that a display of the respective pressure or deflection (d3) corresponding measurement result is shown in the display ( 22 ).

In an industrially economical production of light guide assemblies ( 1 ), which have a pressure sensor ( 2 ) and the optical waveguides ( 3 , 4 ), wide tolerances must be accepted, which cannot easily be compensated for by the evaluation electronics ( 10 ). A comparison of each light guide arrangement within a narrow tolerance range would be complex. In order to avoid deviating countermeasures in the optically effective range, the light guide arrangements ( 1 ) are manufactured in a tolerance range that is easily adhered to in mass production. During the final inspection of each light guide arrangement ( 1 ), the pressure characteristic of the respective light guide arrangement ( 1 ) was run through in a measuring computer. From the comparison of the actual characteristic curve with a standard characteristic curve, the measuring computer calculates adaptation values for the slope and the zero point, which are embodied by ohmic resistances (X, Y). These resistances (X, Y) are used in the plugs of the light guide arrangement ( 1 ). In the case of larger production lines, an intended pair of resistors (X, Y) can also be compared by means of laser adjustment, or a bar coding can be used.

If the light guide arrangement ( 1 ) is then connected to the evaluation electronics ( 10 ), the microcontroller ( 28 ) takes over the resistance values (X, Y) and generates control values (x, y) with which voltage adjustment elements ( 30 , 31 ) (see. Fig. 3) accordingly who the. For this calibration of the bridge circuit, a changeover switch ( 32 ) is provided, which is brought into its position (a) for calibration and into its position (b) for measuring .

In Fig. 6 the pressure sensor ( 2 ) is drawn in a modified compared to Fig. 4. In a bore ( 33 ) of the base body ( 6 ), a Teflon tube ( 34 ) is inserted, which detects the end face of an annular shoulder ( 35 ) of the bore ( 33 ). In the Te flonschlauch ( 34 ) of about 1.0 millimeter inner diameter there is a central inner wedge ( 36 ) which is led out of the front of the Teflon hose ( 34 ) and ends in front of the membrane ( 7 ). Above the inner wedge ( 36 ), the first pair of the optical waveguide ( 3 ) is net angeord, the end exits reach to the membrane ( 7 ). The two pieces of the second, so-called reference light waveguide ( 4 ) are provided on the underside and end at a distance from a shoulder ( 37 ) of the inner wedge ( 36 ). The pairs of optical fibers ( 3 , 4 ) are firmly connected to the inner wedge, which can be done, for example, by shrinking in order to maintain their position precisely.

Claims (6)

1. Pressure measuring device, in particular for medical pressure measurements, with a mechanical pressure sensor, which is connected to an evaluation electronics via an optical waveguide, a light signal being fed to the optical waveguide and transmitting a measurement signal corresponding to the prevailing pressure to the evaluation electronics,
characterized,
that parallel to the optical waveguide ( 3 ) is a comparative optical waveguide ( 4 ) which can be moved together with this bendable and how the optical waveguide ( 3 ) conducts a light signal,
and that the light signal of the comparison Lichtwel lenleiters ( 4 ) from the pressure in the pressure sensor ( 2 ) is unaffected and is fed as a reference signal of the evaluation electronics ( 10 ), which compensates for movement-related changes in the measured value by means of the reference signal. 2. Pressure measuring device according to claim 1, characterized in that in the optical waveguide ( 3 ) and in the comparative optical waveguide ( 4 ) an identical light signal is coupled and in the light path of the comparative optical waveguide ( 4 ) within the evaluation electronics ( 10 ) an actuator ( 13 ) is arranged, which is adjusted by the evaluation electronics ( 10 ) until an optical interference maximum or minimum is reached and the adjustment value is evaluated as a measured value. 3. Pressure measuring device according to claim 1, characterized in that a UHF-modulated light signal is coupled into the optical waveguide ( 3 ) and into the comparative optical waveguide ( 4 ) and the phase shift of the high frequency is evaluated as a measured value. 4. Pressure measuring device according to claim 1, characterized in that the evaluation circuit ( 10 ) detects the electrical voltages (U1, U2) of the optical waveguide ( 3 , 4 ) and the voltage (U2) of the comparative optical waveguide ( 4 ) to a constant value straightened out. 5. Pressure measuring device according to one of the preceding claims, characterized in that the pressure sensor ( 2 ) has a pressure-dependent by bendable membrane ( 7 ) which reflects the Lichtsi signal of the optical waveguide ( 3 ). 6. Pressure measuring device according to one of the preceding claims, characterized in that the comparison optical waveguide ( 4 ) is guided into the pressure sensor ( 2 ) and there it is optically short-circuited depending on the pressure.