RU2231967C2 - Device for measuring arterial blood pressure - Google Patents

Abstract

FIELD: medical engineering.

SUBSTANCE: device has transducer having hydroreservoir, transparent tube, measuring dial and pneumoreservoir. The transparent tube is tightly connected to the transducer hydroreservoir with its first end and to the pneumoreservoir with its second end. The transducer is manufactured as cuff having pneumopump, pneomochamber of which is connected to transducer transforming pressure to change hydroreservoir volume tightly sealed in the hydroreservoir. The pneumoreservoir is a part of transparent tube on the second end side where elastic material cap is mounted. The cap has elastic material cap having hole in its flexible wall.

EFFECT: high accuracy of measurements.

8 cl, 4 dwg

Description

The invention relates to medicine, in particular to diagnostic devices for measuring blood pressure.

A device for measuring blood pressure is already known (for example, the domestic IADM-OP tonometer according to TU-64-1-3878-85), containing a meter and a sensor. The meter contains a circular measuring scale, calibrated, as a rule, in millimeters of mercury (from 20 to 300 mm Hg), and a roller with a gear and an indicator arrow that rotates relative to the measuring scale. The sensor is made in the form of two serial converters: a transducer of measured blood pressure to the pressure of the compression medium (air) and a pressure transducer of the compression medium into the linear movement of the gear rack. The first sensor converter is made in the form of a cuff with a pneumatic blower. The cuff air chamber is connected to the second transducer in the form of a membrane with a gear rack meshing with the meter gear. However, the accuracy of this device is limited due to the small linear stroke of the flat membrane (1.5-2 mm) and due to friction losses in the rack and pinion mechanism of the meter. In this case, the appearance of a pulse wave by the oscillations of the indicator arrow is visually almost indistinguishable.

Also known is a device for measuring blood pressure, published in the description of the invention to the USSR copyright certificate No. 1741776 (M.cl. A 61 B 5/02, application. 15.06.90, publ. 23.06.92). This device contains a sensor with a hydraulic reservoir, a transparent tube and a pneumatic reservoir, the transparent tube being the first end hermetically connected to the hydraulic reservoir of the sensor, and the second to the pneumatic reservoir. The transparent tube is mounted on a panel with a measuring scale. The hydraulic reservoir of the sensor is filled with a compression medium (liquid) and has a contact membrane and a diaphragm located parallel to it, due to which it is a direct converter of the measured blood pressure to the movement of the diaphragm, causing a change in the volume of the hydraulic reservoir.

However, this device does not provide sufficient measurement accuracy due to subjective pressure on the measured object, reducing the amplitude of the pulse wave due to the influence of backpressure of the pneumatic reservoir. It is cumbersome due to the need to use a large volume of compression fluid.

The aim of the present invention is to improve the accuracy of measurement.

This goal is achieved by the fact that in the known device for measuring blood pressure (containing a sensor with a hydraulic reservoir, a transparent tube and a pneumatic reservoir, the transparent tube being the first end hermetically connected to the hydraulic reservoir of the sensor, and the second to the pneumatic reservoir), the sensor is made in the form of a cuff with an air blower, a pneumatic chamber which is connected to a pressure transducer to change the volume of the reservoir, hermetically integrated into the reservoir, and the pneumatic reservoir is part of the ary tube from the second end, which cap is fastened tightly from a resilient material with a hole in its wall elasticity.

As a transducer of pressure pulses to a change in the volume of a hydraulic reservoir, a bellows is used as a mechanism with a sufficiently high sensitivity. The reservoir is filled with a tinted liquid, which is forced out of it into a transparent tube with a decrease in volume. For the convenience of taking readings of pressure values, the transparent tube is mounted on a panel with a measuring scale applied to it.

The length of the measuring scale and, accordingly, the transparent tube is selected as follows.

The scale division price is set, for example, let P ₁ = 1 mmHg, which corresponds to the length l _{1 of} the liquid moving along the transparent tube 5 mm. The measurement limit P ₂ is set equal to 300 mm RT. Art. The length of the transparent tube l ₂ will be l ₂ = P ₂ × l ₁ = 300 × 5 = 1500 mm By setting the inner diameter d of the transparent tube, we determine the necessary volume V of the displaced fluid. For example, if d = 1 mm, then V = 1177.5 mm ³ . Accordingly, the volume V is the maximum expansion volume of the bellows for the given parameters. With a length of fluid movement in a transparent tube equal to 5 mm and corresponding to a pressure of 1 mm Hg, it is easy to visually and accurately see the appearance and disappearance of a pulse wave and read the systolic and diastolic pressure readings. To achieve compactness of the device, a long transparent tube can be bent in the form of a meander or in the form of a spiral, giving the corresponding shape and measuring scale. The device is structurally simple and does not contain parts that are difficult to manufacture.

The embodiment of the invention is illustrated in the drawing, where

in FIG. 1 shows a General view of the device in section with a transparent tube in the shape of a meander;

figure 2 is the same device with a transparent tube in the form of a spiral;

figure 3 is a fragment of the pneumatic reservoir at the moments of release of air in steady state and at the time of air intake, and

figure 4 is a General view of the tonometer in the case.

As can be seen from figure 1, the device for measuring blood pressure contains a sensor made in the form of two serial converters: cuff 1 with a pneumatic pump 2 and a hydraulic reservoir 3, inside of which there is a pressure transducer to change the volume of the hydraulic reservoir 3 in the form of a bellows 4, the meter in the form of a transparent a tube 5 mounted on a panel 6 with a measuring scale that is calibrated in millimeters of mercury (from 20 to 300 mmHg), and a pneumatic reservoir 7. In this case, the transparent tube 5 with the first end A is hermetically connected it is connected to the hydraulic reservoir 3 of the sensor, and the second end B to the pneumatic reservoir 7, formed by a part of the transparent tube 5 from the side of the second end B, on which the cap 8 of elastic material with a hole B (Fig. 3) is tightly fixed in its elastic end wall. The cuff 1 has a pneumatic chamber 9 with two flexible pipes 10 and 11. A pneumatic blower 2 is connected to the input pipe 10, and a hydraulic reservoir 3 is connected to the output pipe 11 through a bellows 4 and a nozzle 12. The bellows 4 is a membrane in the form of a cup with a corrugated cylindrical shell. At the same time, one end of the fitting 12 extends beyond the hydraulic reservoir 3 and is designed to articulate with the outlet tube 11 of the cuff 1, and the other is located inside the hydraulic reservoir 3 and is designed to articulate with the bellow bellows 4. The joints of the fitting 12 with the bellows 4, with the housing of the hydraulic reservoir 3 and c the pipe 11 is securely sealed. At the outlet of the hydraulic reservoir 3, a sleeve 13 is fastened, which is designed for articulation with the end A of the transparent tube 5. The joints of the sleeve 13 with the housing of the hydraulic reservoir 3 and with the transparent tube 5 are securely sealed. The transparent tube 5 may be in the form of a meander (figure 1) or a spiral (figure 2). The transparent tube 5 can be made of glass with fastening to the panel 6 by any known method, for example, brackets. But it can also be accomplished by molding the desired contour in two transparent plates, which, when glued together, form a transparent panel 6 with an internal cavity forming a tube 5.

In the drawings, the design of the transparent tube 5 and its attachment to the panel 6 are not shown for the sake of simplicity. In a preferred embodiment, the measuring scale is made in the form of a coordinate grid graduated in mm. Hg, and is applied to panel 6. However, it is possible that the measuring scale can be applied to the transparent tube 5. A compensation screw 14 is also mounted in the hydraulic reservoir 3, which can take up various positions. Its end is located inside the hydraulic reservoir 3. As shown in Fig. 4, the tonometer is structurally made in the form of a case with a hinged lid 15. The cavity G of the lid 15 serves to lay the cuff 1 with the pneumatic blower 2.

The device operates as follows.

To ensure the operability of the device, the reservoir 3 is filled with a tinted liquid that does not wet the material of the transparent tube 5. As a rule, the liquid is selected such that its surface tension at a given diameter of the transparent tube 5 prevents the outflow of liquid under the action of gravitational forces. To bring the device into working position, the case is opened by turning the cover 15 to the position shown in figure 4. From the cavity G of the cover 15, the cuff 1 is removed with the pneumatic blower 2, and the flexible pipe 11 of the cuff 1 is connected to the fitting 12 (Fig. 4). If necessary, then using the compensating screw 14 (Fig. 1), the volume of fluid in the reservoir 3 is changed by setting the fluid level in the transparent tube 5 at the “0” mark on the measuring scale of panel 6. At the same time, the maximum volume of the reservoir 7 is set from the surface of the fluid at zero point to the inner plane of the cap 8, mounted on the second end B of the transparent tube 5. The cuff 1 is applied and fixed on the patient’s shoulder in accordance with the standards for measuring blood pressure.

Using a pneumatic blower 2, a compression medium (air) is pumped into the pneumatic chamber 9 of the cuff 1 through a flexible inlet pipe 10. At the outlet flexible pipe 11, compressed air through the nozzle 12 is fed into the cavity of the bellows 4, which changes its volume in proportion to the pressure in the pneumatic chamber 9 of the cuff 1, while changing accordingly the volume of liquid in the hydraulic reservoir 3 and forcing the tinted liquid through the opening of the sleeve 13 into the transparent tube 5 through its first end A. Pressure is measured on a measuring scale calibrated in mmHg, fixing the level of tinted liquid in the transparent tube 5. A new volume of pneumatic cutter is installed. of the wool 7 - from the surface of the liquid at the current mark to the inner plane of the cap 8 at the second end B of the transparent tube 5. The volume of air in the pneumatic reservoir 7 is reduced, while remaining under normal pressure due to the presence of the compensation hole B in the cap 8. This hole is due to the elasticity of the wall, in which it is made, has a variable diameter, which varies in direct proportion to the absolute value of the air pressure in the pneumatic tank 7.

The dimensions of the compensation hole B during the release of air in the initial and steady state, as well as during suction are shown in Fig.3.

When pressure builds up in the pneumatic chamber 9 of the cuff 1, the artery lumen is gradually squeezed and the pulse wave of blood flowing through the artery causes oscillatory changes in the pressure of the compression medium in the pneumatic chamber 9 of the cuff 1, and accordingly, the oscillatory changes in the volume of the bellows 4 and the fluid in the system (hydraulic reservoir is transparent pipeline). Fixing the start of oscillation mark on a scale on panel 6, diastolic blood pressure is determined. Continuing to pump the compression medium into the pneumatic chamber 9 of the cuff 1 until the artery is completely squeezed (the pulsation stops), the systolic pressure is recorded. Relieving pressure from the pneumatic chamber 9 of the cuff 1 using the manual valve of the pneumatic blower 2, it is possible to make similar measurements in the reverse order.

Claims (8)

1. A device for measuring blood pressure, comprising a sensor with a hydraulic reservoir, a transparent tube, a measuring scale and a pneumatic reservoir, the transparent tube being the first end hermetically connected to the hydraulic reservoir of the sensor, and the second to the pneumatic reservoir, characterized in that the sensor is made in the form of a cuff with an air blower, a pneumatic chamber which is connected to a pressure transducer to change the volume of the reservoir, hermetically integrated into the reservoir, and the pneumatic reservoir is part of a transparent lips from the side of the second end, on which the cap of elastic material with a hole in its elastic wall is tightly fixed. 2. The device according to claim 1, characterized in that the pressure transducer to change the volume of the reservoir is made in the form of a bellows. 3. The device according to claim 1, characterized in that the transparent tube has the shape of a meander. 4. The device according to claim 1, characterized in that the transparent tube has a spiral shape. 5. The device according to claim 1, characterized in that the transparent tube is mounted to a panel on which a measuring scale is applied. 6. The device according to claim 1, characterized in that the transparent tube is formed by forming a contour in two transparent plates, which, when glued together, form a transparent panel with an internal cavity forming the tube. 7. The device according to claim 1, characterized in that the measuring scale is applied to a transparent tube. 8. The device according to claim 1, characterized in that a compensating screw for changing the volume of liquid is mounted in the hydraulic reservoir.

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