DE626467C - Device for measuring or registering blood pressure using the compensation method - Google Patents

Description

Device for measuring or registering blood pressure according to the compensation method The invention relates to a device for measuring or registering blood pressure according to the compensation method.

In the compensation method, the air pressure is in an arm cuff increased and observed on a manometer until pressure fluctuations occur, which result from the pulse oscillations and their beginning as the lower, the so-called diastolic blood pressure limit is understood. With a further increase in air pressure the pressure fluctuations resulting from the pulse oscillations can be heard in the cuff on, and this cessation of the pulse oscillations is called the upper one, the so-called spstolic Blood pressure limit, which so far has mainly been used as the basis for measuring blood pressure has been laid.

It is known when measuring blood pressure using the compensation method, the cuff to be placed over the humerus artery with a storage container for To connect compressed air and the air supply to the cuff dßk-ch the pulse oscillations to regulate, in such a way that one actuated by the pulse beats over the radial pulse Contact device is attached, which is a valve in the air line between the Affects the air reservoir and the cuff. This known device continues not just the arrangement of two separate devices to be attached to the arm ahead, but it is also not always reliable to the extent that it is too strong, too loose or incorrect application of the contact apparatus impair the measurement result can.

In addition, this known device has the disadvantage that the short. Pulse oscillations only open the air supply valve very briefly Have consequence and that consequently the speed of the air supplied is very high must be in order to produce the required air pressure in the cuff. Which the resulting strong blasts of air in the cuff are incorrectly referred to as Pulse oscillations are registered and the measuring device runs unnecessarily excited, whereby the occurrence of the borderline case, d. H. the time at which the pulse oscillations stop becoming indistinct.

It was with the known devices for the same reason not possible to correctly determine or register the lower blood pressure limit.

The invention eliminates the disadvantages of the known devices eliminated, and it is achieved with the greatest accuracy either the upper or, if necessary that lower blood pressure limit or both continuously determine or-w. to be recorded continuously.

According to the invention, this is done in a device for measuring blood pressure according to the compensation method, with compressed air from an inflatable arm cuff is supplied through a conduit, -which is also sealed with an airtight Space is connected, achieved in that one in a known manner the air supply to the cuff through the pulse rate regulating device in this hermetically sealed space is arranged so that it is through the pulse rate resulting air puffs is controlled. This increases the effectiveness of the device regardless of the absolute pressure level.

Another feature of the invention is the provision of a in the air supply line to the cuff and to the airtight closed space. located regulating organ, which is kept open as long as there are still puffs of air through pulse oscillations emerge from the cuff. This will result in too high a speed the air flowing into the airtight container and the cuff prevented and thus the uncertainty of the measurement avoided. As long as there are still pulse oscillations occur, d. H. as long as the maximum blood pressure has not yet been reached, remains the air supply valve is opened and a low speed is sufficient the steadily flowing air.

According to the invention can also in the hermetically sealed Air blasts occurring in the room on the control device arranged in this room come into effect that either the occurrence or the cessation of the pulse oscillations the air supply to the cuff is interrupted. It is made possible in this way, so, # vohl measure or register the lower as well as the upper blood pressure limit.

In order to create a particularly sensitive facility, the airtight container a contact device in the manner of a moving coil instrument be stored, on one arm the. Acting blasts of air and its other Arm is used to make contact.

The subject matter of the invention is shown in some exemplary embodiments in the drawing shown schematically, namely Fig. i show an embodiment in schematic Representation, fig. a second embodiment, also in schematic Representation, Fig.3 another embodiment in which the means are shown. to measure and / or to measure both the upper and lower blood pressure limits to register; Figs. 4 and 5 show details and Fig. 6 shows a blood pressure diagram for the purpose of explaining the device according to the invention.

According to the embodiment according to Fig. I, the pneumatic arm cuff z by a hose: 2 connected to a nozzle 3, which is closed in an airtight Container. -Projects. In this a two-armed lever 5, 6 is on an axis 7 -stored in the manner of a moving coil instrument. The arm 5 of this lever carries a Kappp, e 8, which usually keeps the mouth of the DÜSee 3 closed while the arm 6 carries a contact piece 9, which when swinging the lever 5, 6 against an adjustable contact screw io pushes, which protrudes from the outside into the container 4., By means of a spring I i, the lever 5, 6 is in the position that closes the nozzle held.

The container 4 stands through a pipe 12 with a bottle 13 in connection in which the compressed air is located. A reducing valve 14 is the Upstream bottle.

The air line has two branches 121 and z2'-. In the branch line 121 there is an electrically controlled valve 15 as well as a throttle valve 16. Another throttle valve 17 is located in the line 1: 2 upstream of the container 4. A line z9 and z91, provided with a throttle valve, leads from the air line 12 to the hose connected to the cuff i 2.

If the valve 15 in the pipe branch 121 is opened with this arrangement, so the air flows out of the bottle i3 into the container 4 as well as into the cuff i. The various throttling devices that are located in the pipelines are coordinated so that the pressure conditions in the container 4 and the cuff i always stay the same.

As soon as the pressure in the cuff i reaches a certain level the pulse oscillations begin, as indicated in Fig. 6 at I a # nge. This pressure level is considered to be the diastolic blood pressure limit. The amplitudes these oscillations have different values among themselves. If the pressure increases in the Cuff continues as a result of the air supply, so hear at a certain height of the Pressure on the oscillations, as indicated in II of Fig.6. This Point is understood as the systolic blood pressure limit.

The filling of the cuff i and the container 4 to the bottom Blood pressure limit is set by opening one of the branches management 12 = located valve 2o, the electrically controlled in the embodiment Valve 15 remains closed. In order now to check the blood pressure conditions on one with the Container 4 connected manometer 2.1 or a recording device of known type running To make visible or to record, the following device has been made: The contact screw io and a second connection 22 to which the spring i i is connected to conduct electricity, are in a circuit that controls a valve 15 influencing Relay 23 is used.

The pulse oscillations cause blasts of air in the cuff i, which emerge from the nozzle 3 and cause the lever 5, 6 to oscillate. With each swinging movement of the lever 5, 6 a contact between 9 and io is made, and a highly sensitive relay, e.g. B. an electron tube 2.s, a current surge is caused in your control relay 23, through which the air valve 15 is opened. The valve 2o is closed here. Since the opening of the valve 15 caused by a blast of air acting on the lever 5, 6 is only of a very short duration and thus the amount of air required to increase the pressure in the cuff i and in the container 4 would have to have a very high speed, is in the circuit of the relay 23 switched on a delay system 24, 31, 25 of a known type, which is selected so that it keeps the contact for the circuit of the control relay 23 closed for about one second. If, after the first impulse, there is a second impulse due to insufficient pressure in the cuff i, normally in humans before another second has elapsed, the time delay for the contact interruption is restarted in the delay relay 25 for about i second before the contact has separated. Only when a pulse has passed, ie point II of the diagram (Fig. 6) has actually been reached, and no more pulse oscillations occur, the circuit is interrupted and valve 15 is closed. As a result of the constant supply of air to the cuff i and to the container .4. the air speed can be kept so low that the air supply does not interfere with the measurement result as in the case of the known devices mentioned above.

The throttle elements 17, i8 t, nd the air lines are arranged in this way and coordinated that the air supplied only through the valve 17, not but through the nozzle 3 into the container and through the valve 18 into the cuff got. In a branch of the air line 12, a throttle member 26 is arranged, that leads to the open air and from your constantly air escapes into the open air, so that the device can follow falling blood pressure.

If the pressure in the cuff i and in the container 4 decreases as a result of the When the air flows out through the throttle member 26, the pulse oscillations occur open again and have an opening, the air supply valve 15 result. This process repeats itself constantly, and by adjusting the contact screw io it is possible to point II, d. H. the upper blood pressure limit, continuously visible on manometer 21 to make or to record using a recording device.

To interrupt the measurement after a certain period of time, is a drain valve 27 is provided in a branch line 28 through which the container 4 and the cuff i can be deflated.

The interruption and restart of the measuring process can of course also take place automatically. A device for this is shown in the exemplary embodiment according to FIG. The device is generally the same as that described with reference to Figure i, but the fill valve 20'1 and the drain valve 27r are electrically controlled. For this purpose, a second, adjustable contact pin 2g is provided in the airtight housing 4, which the lever 5, 6 contacts with a contact piece 30 in its rest position. As a result, a circuit via the contacts 22 and 29, 3o is usually closed, which excites the tube 24.1 connected to this circuit, so that a reversing relay 31 keeps its contact closed. A magnetic switch 33 with the switch coil 34 and a controlled contact 35 are located in a second circuit, which is connected to the reversing relay 31 and which contains the control relay 32 for the filling valve 2o1.

Controlling the contact 35 by means of a cam disk 36 which is mounted on a rotated by a movement shaft 3 7: When the switch 35 closed by the cam 36, so does the magnetic switch 33, 34, and the filling valve 2o1 closes is opened by relay 32, since the circuit for this relay is closed. The air now flows out of the bottle 13 through the lines 12 and ig into the container 4 and the cuff i. Since the magnetic switch 33, 34 remains closed even after the cam disk 36 has released the switch 35, there is a steady flow of air into the cuff i. As soon as the pressure in the latter has risen so far that point I (Fig. 6) is reached, i.e. as soon as the first pulse oscillation occurs, a blast of air from the nozzle 3 acts on the lever 5, 6 and the contact 29, 30 will be interrupted. As a result, the switch coil 34 is de-energized and the valve 2 & 2 closes again.

By the occurrence of the first pulse oscillation and the decay of the contact lever 5, 6, the contact 9, io has been closed, whereby in the In the manner described with reference to Fig. .i, the control relay 23 for the air valve 15 has been opened and blood pressure measurement has started.

After a certain period of time, N N closes a second cam disk 38 attached to the constantly rotating shaft 37, a contact 3g of a circuit for the control relay 4o of the drain valve 271: By closing the contact 39, the control valve 271 is opened, and the air from the cuff i and the housing 4 flows into the open air. As soon as the cam disk 36 closes the switch 35 and the switch 39 opens again, the measuring process is initiated again.

The electrically controlled air valves 23 and 2o1 can, as Fig. 4 shows, consist of a tube 41 in which a rubber hose 42 is located. A spring-loaded plunger 44 presses on the rubber hose through a lateral opening 43 and squeezes it shut. As soon as the coil of the associated control relay de-energizes is flowed through, the plunger is pulled into this coil and the Durahfiuß.opening of the hose released. Of course, the air valves could also be different be designed and opened and closed in a different way.

The embodiment according to Fig. 3 is a device '' which enables the measurement and recording of the lower and upper blood pressure limits. In this device, which is shown in the form of a circuit diagram, are the devices corresponding to the embodiment according to Fig. i with the same Provided with reference characters.

A current flows continuously from the electron tube 24, which is heated from the circuit 45, through the relay 31, which keeps a contact 46 closed. If a contact lever 47 assumes the position shown in FIG. 3, a circuit in which the control relay 23 for the air valve 15 is located is thus closed. The latter is thus open and the air flows out. the bottle 13 through the line i2 to the airtight container 4 and via the junction i9 and the hose 2 to the cuff. As soon as the required air pressure is reached in this and pulse oscillations begin, the contact lever 5, 6 is rotated by the first blast of air emerging from the nozzle 3 against the contact pin io, and a current flows to the grid of the electron tube 24 .. The current flow from the latter is thus interrupted, and the relay 3 i opens the contact 46. As a result, the circuit to the control relay 23 is interrupted, and the valve 15 closes. The lower blood pressure limit has now been reached. As soon as the pressure in the cuff i has decreased as a result of the constant outflow of air from the throttle valve 26 and the blasts of air from the nozzle 3 cease, the contact lever 5, 6 swings back and opens the contact io. The current flow from the electron tube 24 begins again and the contact 46 is closed again by means of the relay 31. As a result, the air supply valve 1 5 is opened again, and the process described is repeated anew. By setting the contact screw accordingly, it is achieved that a writing instrument, for example, only vibrates slightly and deviates little from a straight line.

In order to determine or record the upper blood pressure limit, the switching lever 47 is switched to the lower position in which it touches a contact 48. Through the filling valve 20, the air from the bottle 13 to the airtight container 4 and. the cuff i until the pulse oscillations occur. The valve 2, o is now closed. As soon as blasts of air emerge from the nozzle 3 and the lever 5, 6 closes the contact, the current flowing continuously from the electron tube 24 via the relay 31 and thus the contact 46, as already mentioned, is interrupted. When the contact lever 46 is tilted down, it closes the contact 49, and a current now flows via 46, 49, 48 and 47 to the control relay 23, whereby the air valve 15 is opened. The air supply through valve 1 5 now takes place as long as blasts of air are still emerging from the nozzle as a result of the pulse oscillations. If the pulse oscillations stop, the contact opens and the current flow from the electron tube comes into effect again. The relay 3 1 opens the contact 46, 49, and the air supply valve 15 is closed because the circuit of the control relay 23 is interrupted.

By adjusting the contact screw io, you can also measure the upper blood pressure limit can be achieved that, for example, a writing instrument only makes slight deflections and deviates only slightly from a straight line.

In order to have a steady and steady situation despite the brief contact in the container 4 Inflow of Air to tank q. and to reach the cuff x, is a delay system 25 in the form of a capacitor 50 and a resistor 51 provided.

By setting the contact screw accordingly, it is also OK possible, the amplitudes of the deflections caused by the pulse oscillations to determine or to record the greatest amplitude.

Instead of the contact system shown in the airtight one Container q. a microphone or telephone may be used under certain circumstances, which is influenced by the pressure waves.

In the exemplary embodiments described, it was assumed that that there is only one inflatable organ in the cuff i, which is caused by the Hose line 2 is connected to the nozzle 3 and from which the pulse oscillations caused blasts of air escape. In special cases it may be desirable not to take the air blasts from the actual cuff, but from an inflatable organ that is some distance away from the tourniquet and due to the impulses still occurring above the stasis cuff is not affected. Fig. 5 shows such a cuff il, which is a pneumatic Has cushion 52 as a stasis cuff to which the air line i9 is connected. In the cuff il there is also a second pneumatic cushion 53, which is connected to the nozzle 3 by the hose 2.

Claims (6)

PATENT CLAIMS: i. Device for measuring blood pressure according to the compensation method, in which an inflatable arm cuff is supplied with compressed air through a line, which is also connected to an airtight space, thereby characterized in that one in a known manner the air supply to the cuff by the pulse rate regulating device in this airtight closed room is arranged so that it is controlled by the blast of air resulting from the pulse will. 2. Device according to claim i, characterized by one in the air supply line control element located for the cuff and for the airtight closed space, which is kept open by the puffs of air as a result of the pulse oscillations from the cuff will. 3. Device according to claim i or 2, characterized by one in the airtight closed space arranged electrical control and switching device on the the blasts of air resulting from the pulse oscillations act in such a way that either the occurrence or cessation of the pulse oscillations the air supply to the cuff interrupts to measure either the lower or upper blood pressure limit. q .. Device according to claim 1 or 3, characterized in that one is airtight closed container (q.) a contact device (5, 6, io) in the manner of a Moving coil instrument is mounted, on one arm of which the blasts of air act. 5. Device according to one of the preceding claims, characterized in that that in one with the electrical switching or contact device ("6; io) in connection standing circuit a changeover switch (q.7) is arranged in such a way that the switching or contact device a circuit for the air supply valve (15) for the cuff (i) controlling relay (23) either closes or opens. 6. Establishment according to one of the preceding claims, characterized by a device for periodic control of the filling and emptying valves (2o1, 271) or the like, in such a way that the measurement or recording of the blood pressure is interrupted at certain time intervals and is reintroduced.