RU2176387C2 - Pressure transducer of medium in vessel with elastic walls and procedure measuring pressure of medium - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: pressure transducer of medium in vessel with elastic walls has body in which butt recess is made and membrane having mirror reflecting surface facing fiber-optical converter-probe of membrane displacement is anchored. Converter-probe has emitting and detecting light guides and is fixed in duct of body with clearance with reference to membrane. Enclosure is made of material whose hardness is substantially higher than hardness of elastic wall of vessel and is made fast to body coaxially to it so that it protrudes beyond body and forms protrusion which length is equal or longer than dimension of body. Axially symmetric indenter which length is equal to length of protrusion of enclosure is attached to membrane on side of protrusion so that butt of indenter and butt of protrusion contact elastic wall of vessel. Given pressure transducer can be employed to measure pressure of medium in vessel with elastic walls as well as blood pressure in blood-vessels. EFFECT: enhanced functional reliability and widened application field. 10 cl, 3 dwg

Description

 The present invention relates to the field of measuring technology, and more specifically to a pressure sensor of a medium in a container with elastic walls, to a method of measuring pressure by said sensor and to a method of measuring blood pressure in a blood vessel.

 The specified sensor can be used to measure the static and dynamic pressure of a liquid, gas, fluidized powdery media in an elastic channel, in a pipeline, in the body’s vessels without opening the vessel wall or capacity, and also to diagnose the cardiovascular system by a pulse wave, including determining a violation heart rate, pulse rate, pulse pressure, the maximum intensity of the ejection of blood from the left ventricle, the time of expulsion of the left ventricle, the parameters of the aortic valve a, the elasticity index of the great vessels, the physiological age of the great vessels, the simultaneous study of the electrical activity of the heart muscle and the mechanical work of the heart and blood vessels in real time.

 The closest technical solution is a medium pressure sensor containing a housing, at the end of which a recess is made and a membrane is mounted, having a mirror reflective surface facing the fiber-optic transducer-probe for displacing the membrane, having emitting and receiving optical fibers and fixed in the channel of the housing with a gap relative to membranes (see, for example, US patent 3580082, 1969).

 In said sensor, optical fibers direct collimated light to a membrane that reflects it. In the immediate vicinity of the light guide fibers, light receiving fibers are arranged, which are connected to a light intensity measuring unit. When the membrane is deflected, the direction of the reflected light changes, therefore the amount of light entering the light-receiving fibers changes. The resulting change in light intensity is transmitted to the measuring unit and serves as a measure of the deflection of the membrane, i.e. pressure exerted on the membrane.

 The specified sensor does not allow the measurement of static and dynamic pressure of liquid, gas, fluidized powder media in an elastic channel, in a pipeline, in vessels with elastic walls without opening the vessel wall or vessel.

 The basis of the present invention is the task of creating a sensor of the parameters of the pressure of the medium in a tank with elastic walls, which would allow measurements of the static and dynamic pressure of a liquid, gas, fluidized powder media in an elastic channel, in a pipeline, in the vessels of the body without opening the wall of the vessel or tank, and also to carry out the diagnosis of the cardiovascular system by the pulse wave, including the determination of heart rhythm disturbance, pulse rate, pulse pressure, maximum inter nsivnost of the ejection of blood from the left ventricle, the time of expulsion of the left ventricle, the parameters of the aortic valve, the index of elasticity of the main vessels, the physiological age of the main vessels, a simultaneous study of the electrical activity of the heart muscle and the mechanical work of the heart and blood vessels in real time.

 The problem is solved in that the pressure sensor of the medium in a container with elastic walls, comprising a housing, at the end of which a recess is made and a membrane is mounted, having a mirror reflective surface facing the fiber-optic transducer-probe for displacing the membrane, having emitting and receiving optical fibers and fixed in the channel of the housing with a gap relative to the membrane, according to the invention contains a casing made of a material whose hardness is significantly greater than the hardness of the elastic wall of the tank rigidly fixed to the housing coaxially with the housing so that it protrudes beyond the housing and forms a protrusion whose length is equal to or greater than the defining size of the housing, while an axisymmetric indenter coaxially fixed on the membrane side is approximately equal to the length of the protrusion of the casing, so that the end face the indenter and the end face of the protrusion are intended for contact with the elastic wall of the tank.

 It is useful that the casing is placed on the housing with the ability to change its position along the longitudinal axis of the housing to change the length of the protrusion.

 Advantageously, the casing is secured to the housing by means of a threaded connection.

 It is also useful that the casing is secured to the housing by means of a collet connection.

 It is advisable that the indenter was made of a material whose hardness is substantially greater than the hardness of the elastic wall of the container.

 It is useful that the indenter be fixed to the membrane by means of glue, which retains its elastic properties when set.

 The problem is also solved by the fact that in the method of measuring the pressure of a medium in a container with elastic walls according to the invention, a pressure sensor is pressed against the vessel wall, the elasticity of which is 10 or more times greater than the membrane’s elasticity, while the indenter end and the end face of the protrusion are in contact with the elastic wall of the vessel and ensure the deflection of the membrane in a given range, measure the change in the gap between the membrane and the end of the fiber-optic transducer probe, convert the change in the gap between the membrane and the end of the fiber-optic transducer probe into a change in the reflected light flux proportional to the change in pressure in the tank.

 The problem is also solved by the fact that in the method for measuring blood pressure in a blood vessel according to the invention, a pressure sensor is pressed against the patient’s skin above the blood vessel, the elasticity of which is 10 times or more the membrane’s elasticity, while the indenter end and the end face of the protrusion non-invasively contact the elastic wall blood vessel through the skin and provide deflection of the membrane in a given range, measure the change in the gap between the membrane and the end of the fiber-optic transducer probe, pre They indicate the change in the gap between the membrane and the end of the fiber-optic transducer probe into a change in the reflected light flux proportional to the change in pressure in the blood vessel, and the amount of the reflected light flux is transformed into a pulse wave, according to which the cardiovascular system and stress state are diagnosed according to the program organism.

 It is advisable that in the diagnosis of the cardiovascular system by pulse wave, heart rhythm disturbances, pulse rate, pulse pressure, maximum intensity of blood ejection from the left ventricle, time of expulsion of the left ventricle, aortic valve parameters, elasticity index of the main vessels, physiological age of the main vessels are determined .

 It is useful that to determine the static blood pressure an additional information channel for ECG measurement is established, the phase shift between the ECG signal and the pulse wave is determined, and the static blood pressure and pulse wave speed are determined using a computer algorithm.

The invention is further explained in the description of a specific variant of its embodiment with reference to the accompanying drawings, in which:
FIG. 1 shows a medium pressure sensor (longitudinal section) according to the invention;
FIG. 2 is a block diagram of an apparatus for measuring a pressure of a medium according to the invention;
FIG. 3 is a pulse wave diagram according to the invention.

 The medium pressure sensor in the tank with elastic walls contains a housing 1 (Fig. 1), at the end 2 of which a recess 3 is made and a membrane 4 is fixed. The membrane 4 has a mirror reflective surface 5 facing the fiber-optic transducer probe 6 for displacing the membrane. The transducer probe 6 has emitting and receiving optical fibers 7, 8 and is fixed in the channel 9 of the housing 1 with a gap 10 relative to the membrane 4.

 The pressure sensor also includes a casing 11 made of a material whose hardness is substantially greater than the hardness of the elastic wall of the container 12. The casing 11 is mounted on the housing 1 coaxially with the housing 1 so that it protrudes beyond the housing 1 and forms a protrusion 13, the length of which is equal to or greater than the size of the housing 1.

 Moreover, from the side of the protrusion 13, an axisymmetric indenter 14 is coaxially fixed to the membrane 4, the length of which is equal to the length of the protrusion 13 of the casing 11, so that the end face of the indenter 14 and the end of the protrusion 13 are intended for contacting the elastic wall of the container.

 The casing 11 is placed on the housing with the ability to change its position along the longitudinal axis of the housing to change the length of the protrusion. There are various options for securing the casing to the housing.

 In the described embodiment, the casing 11 is mounted on the housing 1 by means of a threaded connection. A variant is possible when the casing 11 is mounted on the housing 1 by means of a collet connection.

 The indenter 14 is made of a material whose hardness is greater than the hardness of the elastic wall of the container 12. The indenter 14 is fixed to the membrane 4 by means of an adhesive that retains its elastic properties when set.

 The method of measuring the pressure of the medium in a tank with elastic walls is as follows.

 Previously, the sensor 15 (Fig. 2) is calibrated depending on the elasticity of the wall material.

 The pressure sensor 15 is pressed against the wall 12 (Fig. 1) of an elastic vessel, the elasticity of which is 10 times or more greater than the elasticity of the membrane 4. In this case, the end face of the indenter 14 and the end face of the protrusion 13 are in contact with the elastic wall of the container 12 and provide deflection of the membrane 4 in a given range .

 The signal is amplified on the amplifier 16 (Fig. 2), the signal is converted on the analog-to-digital converter 17 and, through the galvanic isolation unit 18, is supplied to the computer system unit 18, and then displayed on the display 20.

 The change in the size of the gap 10 (Fig. 1) between the membrane 4 and the end of the fiber-optic transducer-probe 6 is measured.

 The change in the gap between the membrane 4 and the end of the fiber-optic transducer probe 6 is converted to a change in the reflected light flux proportional to the change in pressure in the tank.

 The method of measuring blood pressure in a blood vessel is as follows.

 The pressure sensor 15 is pressed against the patient’s skin over a blood vessel, the elasticity of which is 10 times or more the elasticity of the membrane 4. In this case, the end face of the indenter 14 and the end face of the protrusion 13 non-invasively contact the elastic wall of the blood vessel through the skin and provide deflection of the membrane 4 in a predetermined range.

 The change in the gap between the membrane 4 and the end of the fiber-optic transducer-probe 6 is measured. The change in the gap between the membrane 4 and the end of the fiber-optic transducer-probe 6 is transformed into a change in the reflected light flux proportional to the change in pressure in the blood vessel. The magnitude of the change in the reflected light flux is converted into a pulse wave (Fig. 3), according to which, according to the developed program, diagnostics of the cardiovascular system and the stress state of the body are carried out. In FIG. Figure 3 shows a diagram of the change in pressure in a blood vessel in time with heart beats, where time t (sec) is plotted on the abscissa axis, and blood pressure p (mmHg) is plotted on the ordinate axis. At the same time, in sections 1 and 11 a diagram of a normal pulse wave is shown, and in section 111 there is a deviation from the norm — extrasystole.

 When diagnosing the cardiovascular system using a pulse wave, a special algorithm is used to determine cardiac arrhythmias, pulse rate, pulse pressure, maximum intensity of blood ejection from the left ventricle, time of expulsion of the left ventricle, aortic valve function parameters, elasticity index of the main vessels, physiological age of the main vessels .

 To determine the static blood pressure, an additional information channel for ECG measurement is established. The phase shift between the ECG signal and the pulse wave is determined, and the static blood pressure and pulse wave speed are determined by computer-aided processing according to a predetermined algorithm.

Claims (10)

 1. A medium pressure sensor in a container with elastic walls, comprising a housing, a recess is made at its end and a membrane is mounted having a mirror reflective surface facing a fiber optic transducer-probe for displacing the membrane, having emitting and receiving optical fibers and fixed in the channel of the housing with a gap relative to the membrane, characterized in that it contains a casing made of a material whose hardness is greater than the hardness of the elastic wall of the tank, mounted on the housing coaxially with the housing so that it protrudes beyond the housing and forms a protrusion, the length of which is equal to or greater than the size of the housing, while on the side of the protrusion an axisymmetric indenter is coaxially fixed to the membrane, the length of which is equal to the length of the protrusion of the casing, so that the end of the indenter and the end of the protrusion are intended for contact with an elastic wall capacities.  2. The sensor according to claim 1, characterized in that the casing is placed on the housing with the possibility of changing its position along the longitudinal axis of the housing to change the length of the protrusion.  3. The sensor according to claim 1, characterized in that the casing is mounted on the housing by means of a threaded connection.  4. The sensor according to claim 1, characterized in that the casing is mounted on the housing by means of a collet connection.  5. The sensor according to claim 1, characterized in that the indenter is made of a material whose hardness is substantially greater than the hardness of the elastic wall of the container.  6. The sensor according to claim 1, characterized in that the indenter is fixed to the membrane by means of glue, which, when set, retains elastic properties.  7. A method of measuring the pressure of a medium in a container with elastic walls, which consists in pressing a pressure sensor against the wall of the vessel, the elasticity of which is 10 or more times the elasticity of the membrane, while the end of the indenter and the end of the protrusion are in contact with the elastic wall of the container and provide deflection membranes in a given range, measure the change in the gap between the membrane and the end of the fiber-optic transducer probe, convert the change in the gap between the membrane and the end of the fiber-optic transducer Atelier probe in the change in the reflected light flux is proportional to the change in pressure in the tank.  8. A method of measuring blood pressure in a blood vessel, which consists in pressing a pressure sensor to the patient’s skin over a blood vessel, the elasticity of which is 10 or more times the membrane’s elasticity, while the indenter end and the end face of the protrusion non-invasively contact the elastic wall of the blood vessel through the skin and ensure the deflection of the membrane in a given range, measure the change in the gap between the membrane and the end of the fiber-optic transducer probe, convert the change in the gap between brane and the end of the fiber optic transducer probe to the change of the reflected luminous flux proportional to the change in pressure in the blood vessel is converted into the amount of change in the reflected light beam pulse wave at which is performed according to the program diagnosis of cardiovascular and stress state of the organism.  9. The method according to claim 8, characterized in that in the diagnosis of the cardiovascular system using a pulse wave, violations of the heart rhythm, pulse rate, pulse pressure, the maximum intensity of the ejection of blood from the left ventricle, the time of expulsion of the left ventricle, the parameters of the aortic valve, elasticity index of the great vessels and the physiological age of the great vessels.  10. The method according to claim 8, characterized in that for determining the static blood pressure an additional ECG measurement information channel is established, the phase shift between the ECG signal and the pulse wave is determined, and the static blood pressure and pulse wave speed are determined by computer processing according to a predetermined algorithm.

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