HU196899B - Blood-pressure apparatus - Google Patents

Abstract

The device uses an inflatable cuff (1) and a manometer (3), with a pulsed wave source (4) between the cuff (1) and the body of the patient in the propagation direction of the wave pulses. The signal from the pulse wave source (4) is recorded. The pulsed wave source (4) uses a piezoelectric plate with a resilient conductive layer applied to each of its working surfaces. One of these layers is covered by a resilient insulating layer, in turn covered by a third resilient conductive layer. - Pref. the second conductive layer applied to the other working surface similarly has applied insulating and conductive resilient layers.

Description

The invention can be used to measure arterial blood pressure in patients of all ages, either in health care facilities or even by the patient himself. From US Patent Application 65 17 86, a blood pressure measuring device is known having a manometer-connected pneumatic pressure sensor cuff and an acoustic transducer disposed between the pressure sensor cuff and the patient's body surface under the transverse axis of the cuff with respect to its direction of propagation.

The transducer comprises a housing, a piezoelectric plate fixed in the housing and a connector located in the center of the piezoelectric plate. As a result of the pressure change in the pneumatic pressure sensor cuff, the pulse wave vibrations in the tissues are detected by the piezoelectric disc through a connector and converted into an electrical signal which is transmitted to the recorder.

The disadvantage of the above device is that the accuracy of the arterial blood pressure measurement of the sound signal sensor is relatively low due to the fact that the sound transmitter is useful outside of the presence of acoustic foreign noises, pressure pulsations within the pneumatic cuff and possible muscle contractions also receives unwanted signals. A further disadvantage is that the known transmitter does not allow the measurement of arterial blood pressure in small children, since in this case the useful signal level is very low and therefore the transmitter cannot distinguish it from background noise.

From US Patent No. 89,554,05, a blood pressure measuring device is known having a pneumatic pressure sensing cuff, a manometer and a pulse wave transducer connected to a recording device, the latter being disposed between the pneumatic cuff and the patient's body surface in the direction of propagation of the pulse wave.

The pulse wave transducer has a housing and a piezoelectric plate having a first elastic conductive layer on one working surface and a second elastic conductive layer on the second working surface. The piezoelectric plate is arranged in the housing and connected to a connector.

As the pulse wave travels under the transducer, angular fluctuations occur in the connector, which the piezoelectric plate converts into an electrical signal proportional to the oscillation amplitude, which electrical signal is transmitted to the rotating device.

The disadvantage of the above blood pressure measuring device is that the pulse-wave transducer housing, in conjunction with the pneumatic cuff and the patient's body surface, may cause interference signals, resulting in a decrease in the accuracy of blood pressure measurement. It is further disadvantageous that the transducer used is relatively large and therefore not very suitable for measuring the blood pressure of young children.

It is an object of the present invention to provide a device for measuring arterial blood pressure that enables accurate measurement of blood pressure in young children.

Therefore, the task to be solved is to develop a beacon capable of achieving the above objective.

SUMMARY OF THE INVENTION The object is solved by providing a blood pressure measuring device having a manometric space-mounted pneumatic cuff and a pulse wave transducer disposed between the pnu.matic cuff and the patient's body surface under the transverse axis of the pneumatic cuff with respect to the direction of pulse wave propagation; connected to a recording device, wherein the jitter wave transducer has a piezoelectric plate, each having a resilient conductive layer disposed on each of its working surfaces; according to the invention, an elastic island layer is provided on the surface of the pre-elastic quiver and a further elastic top layer is provided on its surface.

According to the invention, a second elastic insulating layer is provided on the surface of the second elastic conductive layer.

It is also advantageous to arrange a fourth elastic receiving layer on the surface of the second elastic insulating layer. According to the invention, forming 'mlzushullám encoder allows the tissues pulzushuilám ranging> en ATI into electrical signals akításában take ^r bt entire surface of the piezoelectric plate and bizksít good mechanical connection between ajeladó and the patient's body surface area, which együtesen pulse wave transducer a sign of sensitivity. ' results in a significant increase in the volume of the piezoelectric discs of the piezoelectric discs of the they do not distort the piezoelectric plate and therefore cause no disturbance.

A further advantageous effect of the invention is that it provides an opportunity to reduce the size of the pulse wave transmitter. Together, this increases the accuracy of arterial blood pressure measurement and provides the ability to measure blood pressure in young children.

According to the invention, it is expedient to form the first or second elastic conductive layer in at least two portions arranged one after the other in the direction of propagation of the pulse wave.

The latter design of the pulse wave transducer results in a low noise level even when the patient is moving during the blood pressure measurement, since the pulse wave is alternately applied to the elastic conductive layer and a low noise signal is output from the transducer output.

According to the invention, it is also expedient to provide the elastic vczclőrétcgckcl or any of these with reinforcing ribs perpendicular to the direction of propagation of the pulse wave.

Similarly, at least one of the elastic insulating layers is provided with reinforcing ribs perpendicular to the direction of propagation of the pulse wave.

The reinforcing ribs improve both the immunity and mechanical strength of the pulse wave transducer.

The invention will now be described with reference to the drawing.

In the drawing:

Figure 1 is a schematic diagram of an exemplary embodiment of a blood pressure monitor according to the invention;

2-7. Figs

196,899 pulse wave transmitters used in a different measuring device, as an example! the embodiment shown in section;

Figure 8 is a diagram illustrating the interaction of his pulse waves and pulse wave emitter;

Figure 9 illustrates an exemplary form of the pulse wave transmitter output signal as it passes under the pulse wave transmitter.

As shown in Figure 1, the pneumatic cuff 1 of the blood pressure measuring device of the invention can be secured to the body surface 2 of the patient, the pneumatic cuff 1 and the body surface 2 of the patient with respect to the direction of propagation of the pulse wave. having a pulse wave transducer 4 arranged below the transverse axis 5 of the cuff and a recording device 6 electrically connected therewith.

The recording device 6 is preferably implemented as a self-recording device which records the output signal of the pulse wave transmitter 4. An air pump 7 is connected to the pneumatic cuff 1.

As shown in Figure 2, the pulse wave transducer 4 is formed from a piezoelectric plate 8 having an elastic conductive layer 9 on one working surface and an elastic conductive layer 10 on the other working surface. The elastic conductive layers 9 and 10 are connected to the recording device 6 via electrical wires 11.

The arterial blood pressure is measured using the device of the invention as follows:

By actuating the air pump 7, an excess pressure is created in the pneumatic cuff 1, which is increased until the blood flow in the artery stops. Then, the pressure in the pneumatic cuff 1 is gradually reduced and the time of passing the first pulse wave under the pneumatic cuff 1 is recorded by the pulse wave transducer 4 and the recording device 6. The pressure is distributed below the pneumatic cuff 1 so that its maximum value is taken below the transverse axis 5 of the pneumatic cuff 1. Therefore, in order to record the time of the pulse wave passing through the whole of the pneumatic cuff 1, the pulse wave transducer 4 should be arranged below the transverse axis 5.

At the time of the first pulse wave passing through the 4 pulse wave transducers, the pressure in the pneumatic cuff corresponds to the systolic value of arterial blood pressure, whereas at the last pulse wave when the artery is fully "open", the pressure in the pneumatic cuff 1 equivalent to.

As shown in Figure 2, an elastic insulating layer 12 is provided on the surface of the elastic conductive layer 9 and an elastic conductive layer 13 on its surface. The elastic conductive layer 13 provides shielding of the piezoelectric plate 8 against foreign electromagnetic fields, and the elastic insulating layer 12 serves to seal between the elastic conductive layer 9 and the elastic conductive layer 13.

In the embodiment of pulse wave transducer 4 shown in Figure 3, an elastic insulating layer 14 is disposed on the surface of the elastic conductive layer 10, which provides for the perfect contact of the pulse wave transducer 4 on the patient's body surface.

Figure 4 illustrates an embodiment of the pulse wave transducer 4 having an additional elastic conductive layer 15 on the surface of the elastic insulating layer 14, which serves to shield the piezoelectric plate 8 against foreign electromagnetic fields.

In the construction of the pulse wave transducer 4 according to the invention, it participates in sensing the pulse wave passing through the pulse wave transducer 4 with the entire surface of the piezoelectric plate 8, while reducing its effect on blood circulation during blood pressure measurement.

The sensitivity of the pulse wave transducer 4 used in the blood pressure measuring device according to the invention is thus significantly increased and the disturbance of the pulsations in the pneumatic cuff 1, the muscle contractions at the location of the pulse wave transducer 4 and the external electromagnetic disturbances are significantly reduced. All of this allows the pulse wave transducer 4 to be implemented in smaller sizes, to increase the accuracy of arterial blood pressure measurement, and to use the blood pressure monitor for measuring the blood pressure of young children.

Fig. 5 shows an embodiment of the pulse wave transducer 4, wherein one elastic conductive layer, for example elastic conductive layer 9, is made up of two portions of guide plates 16 and 17 arranged one after the other in the direction of propagation of the pulse wave.

The variations of the pulse wave transducer 4 according to Figures 6 and 7 are provided with deflection ribs perpendicular to the direction of propagation of the pulse waves. The pulse wave transducer 4 of FIG. reinforcing ribs 18 are provided on the elastic conductive layer 10, and reinforcing ribs 19 are provided on the elastic insulation layer 14 at the pulse wave transducer 4 of Fig. 7.

The reinforcing ribs 18 and 19 arranged above prevent any possible deflection of the piezoelectric plate 8 other than the direction of propagation of the pulse wave, which increases the interference safety of the pulse wave transducer 4. A further advantage of the reinforcing ribs 18 and 19 is that they increase the mechanical strength of the pulse wave transducer 4.

The electrical measurement signal as shown in Figure 8 is formed as follows: the length of one pulse wave velocity _V propagates along the arrow mark length r = 1 / V can be described by _the equation. The pulse wave transducer 4 will be subjected to several successive deflections, causing its output to display an electrical signal similar to that of FIG. 9, which is fed to the recording device 6. The signal duration τ, as indicated in Figure 9, can be expressed as follows:

τ = t ₂ -tj;

wherein time t _{2 represents} the beginning of the passage of its pulse waves below the 4 pulse transmitters, and time t ₂ represents the end of the passage of the pulse waves below the 4 pulse waves.

196,899

The embodiment of the pulse wave transducer 4 according to FIG. 5 provides an opportunity to detect time-shifted signals 20 and 21 (FIG. 9). This time offset can be used as an informative feature for the passage of the pulse wave below the pulse wave transducer 4, which allows to increase the reliability of the pulse wave transducer 4 during pressure measurement, resulting in increased accuracy in arterial blood pressure measurement in both adult and pediatric patients.

7, a moisture barrier layer 22 is provided on the surface of the outer elastic conductive layer 13. The moisture barrier layer 22 is illustrated in FIGS. The same applies to the variants shown in FIGS.

The use of the pulse wave transducers 4 in the drawing in blood pressure measuring devices results in an increase in the accuracy of arterial blood pressure measurement.

Claims (6)

Claims A blood pressure measuring device having a pneumatic cuff and a pulse wave transducer connected to a manoniometer, disposed between the pneumatic cuff and the patient's body surface under the transverse axis of the pneumatic cuff in relation to the direction of propagation of the pulse and connected to a pulse recorder, a sheet having a first and a second elastic conductive layer on each of its working surfaces, characterized in that on the surface of the first elastic conductive layer (9) there are ₅ elastic insulating layers (12) and on its surface a third elastic conductive layer (13) . Blood pressure measuring device according to claim 1, characterized in that a second elastic insulating layer (14) is arranged on the surface of the second elastic conductive layer (10). Blood pressure measuring device according to claim 2, characterized in that a fourth elastic conductive layer (15) is arranged on the surface of the second elastic insulating layer (14). Blood pressure monitor according to Claim 1 or 2, characterized in that the first or second elastic conductive layer (9 or 10) consists of at least two parts arranged one behind the other in the direction of propagation of the pulse wave. Blood pressure monitor according to claim 3, characterized in that at least one of the elastic conductive layers (9, 10, 13, 15) is provided with reinforcing ribs (18) perpendicular to the direction of propagation of the pulse wave. Blood pressure monitor according to claim 3, characterized in that at least one of the elastic insulating layers (12,14) is provided with reinforcing ribs (19) perpendicular to the direction of propagation of the pulse wave.