DE3725909A1 - Device for measuring blood pressure - Google Patents

Abstract

Published without abstract.

Description

Sphygmomanometers designed for manual operation are formed, have a base body on which a Pressure generator in the form of a rubber ball pump, a pressure measuring mechanism, a connection for a connecting line to a Measuring collar and a drain valve are arranged. in the Inside this body there is a cavity that the connections of the mentioned parts of the blood pressure monitor connects with each other. When inflating the pressure system using the rubber ball pump inevitably kick violently Pressure surges on. These arrive proportionately short connecting line inside the body also directly to the pressure measuring unit. There they put the Pointer of the pressure measuring device in violent vibrations. Since the Operator already the pointer of the pressure measuring mechanism watch when inflating to see if the desired pressure in the printing system has already been reached or not, and also to note that a certain maximum pressure is not exceeded, these are violent Vibration movements or trembling movements of the pointer very much irritating. When approaching the intended maximum Pressure in the printing system must be the operator after a Wait until the rubber ball pump is actuated until the The pointer has calmed down again before the rubber ball pump can press again. This hinders a quick through leadership of blood pressure measurement and also brings Irritation with itself.

The invention specified in claim 1 is the object based on designing a blood pressure monitor so that when Inflating the pressure system's vibrations or tremors movements of the pointer of the pressure measuring mechanism at least be reduced or avoided altogether.

The fact that between the connection point for printing generator and the measuring sleeve on the one hand and the connection place a throttling point on the other hand for the pressure measuring device is switched on, when you press the rubber Ball pump not or inevitable pressure surges very weakly let through to the pressure measuring device, while at the same time the relatively large volume of Measuring collar and the connecting line therefore to dismantle the Contribute pressure surges in front of the pressure measuring unit. In this way the pointer only moves as far as the pressure corresponds in the increase in the printing system, without it in Vibrations. In this way, the operator person calmly observe the pointer of the pressure measuring device and also immediately recognize when the desired final pressure is reached is. Because this inflation of the pressure system very quickly can also precede the examiner through the Blood pressure measurement no longer affects than it does for that Inflate and the measuring process is absolutely necessary.

In an embodiment of the blood pressure monitor according to Claim 2 is the throttling of the pressure surges achieved that the valve housing of the drain valve so is formed that it is the connecting line to the pressure Outside completely blocked and the air passage only through a circumferential groove in the valve housing Area of the connecting line is made possible. These Circumferential groove can very much with regard to the passage cross section easy on the needs of the blood pressure monitor be coordinated. Through the through hole in the wall  the valve housing for the drain valve becomes the connection made between the drain valve and the pressure system. By training the blood pressure meter after Claim 3 is achieved in that the valve housing none special orientation with regard to its angular position in the Basic housing is required so that in any case a sufficient Flow cross-section to the drain valve is free.

In an embodiment of the blood pressure monitor according to Claim 4 is the presence of a closing spring in Interior of the valve housing of the drain valve, to by at least in the area of the connecting line located and relatively close to each other Coils of the coil spring split the passage cross-section on several very small passage cross-sections to achieve and thus a corresponding throttling of the Pressure surges in the direction of the pressure behind to reach the measuring device.

The invention is based on two in the Drawing illustrated embodiments closer explained. Show it:

Figure 1 is a fragmentary and partially sectioned view of a first embodiment of the blood pressure meter.

Fig. 2 is a fragmentary and partially sectioned view of a second embodiment of the blood pressure monitor.

The blood pressure monitor 10 shown in FIG. 1 has an elongated, slender basic housing 2 . At its lower end in the drawing, a rubber ball pump 12, only partially shown, is attached as a pressure generator for the blood pressure monitor 10 . The basic housing 11 has in its interior a cavity 13 extending in the longitudinal direction of the basic housing, which is composed of sections of hollow cylinders with different diameters and different lengths. In the lower section there is an inlet valve 14 in the usual design with a slotted valve hose. Also in the lower region of the base body is arranged in a perpendicular to the longitudinal axis 15 of the base body 11 through hole of its wall, a connecting piece 16 is arranged, which is used to connect a connecting hose, not shown, to the measuring sleeve.

At the side facing away from the rubber ball pump 12 end portion of the base housing 11, a threaded hole 17 is mounted which communicates with the cavity 13 of the base housing 11 in combination. The threaded hole 17 is arranged on the upper side of the basic housing 11 when handling the blood pressure measuring device 10 , which in FIG. 11 faces the viewer. The longitudinal axis of the threaded hole 17 can be inclined with respect to the longitudinal axis 15 of the basic housing, generally away from the rubber ball pump 12 . By means of this threaded hole 17 , a pressure measuring device 18 is connected to the basic housing 11 , which is not shown in FIG. 1, but is only indicated by a few circular outlines, since in practice it is located above the basic housing 11 and, in its representation, the one below it would largely cover lying parts.

On the side facing away from the connecting piece 16 of the basic housing 11 , a drain valve 19 is arranged. It has its own valve housing 21 . A hollow conical valve seat 22 is arranged therein. A slender valve cone 23 interacts with this. It is pressed against the valve seat 13 in the outward direction by a closing spring 24 . The valve cone 23 is actuated by a screw cap 25 in the opening sense, which is adjustable by means of a steep thread on the valve housing 21 .

As can be seen from Fig. 1, the longitudinal axis 26 of the drain valve 19 includes an angle with the longitudinal axis 15 of the base body 11 , which is preferably 60 °, wherein the drain valve 19 of the rubber ball pump 12 is inclined. The valve housing 21 has at the end facing away from the screw cap 25 a circular cylindrical housing part 27 which is inserted into a matching recess 28 in the base body 11 and is sealed therein by means of a seal 29 to the outside. The recess 28 extends from one side of the base body 11 through the cavity 13 through into the wall on the other side of the cavity 13 . The housing part 27 used therein of the valve housing 21 therefore extends through the section of the hollow space 13 located there and separates it into the two subspaces 31 and 32 . In the housing part 27 of the valve housing 19 there is a through hole 33 which passes through both walls and which is at least approximately aligned with the longitudinal axis of the cavity 13 . In the simplest case, this through hole 33 is produced in that, after the valve body 21 has been inserted into the base body 11, its housing part 27 is pierced from the subspace 32 , the subspace 31 of the cavity 13 likewise being produced, ie drilled, for the sake of simplicity.

As can be seen from Fig. 1, the interior of the portion 27 of the valve housing 21 is largely filled by the closing spring 24 , which is guided through the inner surface of the wall of the portion 27 . At least in the area of the through-hole 33 , the closing spring 24 is made with spring turns which are closely adjacent to one another, but which are not yet in contact with one another in the closed position of the drain valve 19 . The spaces between the individual bonds of the closing spring 24 are so narrow that they serve as a throttle for the air flow which is pumped into the pressure system by the rubber ball pump 12 and which is initially through the cavity 13 into the subspace 31 and from there at the throttle point past in the subspace 31 and finally through the threaded hole 17 into the pressure measuring device. Since the described throttle point is located between the pressure generator formed by the rubber ball pump 12 and the Druckmeßwerk 18, the ball from the rubber pump 12 pressure pulses generated are largely by the pressure measuring unit kept 18th

In the apparent from Fig. 2 blood pressure meter 35 , only the shut-off valve 36 against the shut-off valve 19 is partially modified. All the other parts are the same as those of the blood pressure meter 10 .

The valve housing 37 of the drain valve 36 here also has a circular-cylindrical housing part 38 which is inserted into the recess 28 of the basic housing 11 and therefore separates the two subspaces 31 and 32 of the cavity 13 from one another. In the area of these two sub-spaces 31 and 32 , the housing part 38 has a circumferential groove 39 . This circumferential groove establishes the connection from subspace 31 to subspace 32 . Their dimensions are chosen so that they also form a throttling point for the pressure surges when the air is pumped into the pressure system by means of the rubber ball pump 12 .

The connection from the cavity 13 of the basic housing 11 to the drain valve is made through two pairs of through holes 41 and 42 which are provided in the region of the circumferential grooves 39 in the wall of the larger section 38 . The longitudinal axes of the through holes 41 and 42 are oriented perpendicular to the longitudinal axis of the drain valve 36 and at the same time perpendicular to each other. This ensures that there is a sufficient passage cross section to the drain valve 36 , regardless of the angular position of the axis cross of the through holes 41 and 42 with respect to the longitudinal axis 15 of the base body 11 .

Claims (4)

1. Blood pressure monitor with the features:

• - On a hollow base body there are at least one connection for a pressure generator, for a measuring sleeve, for a pressure measuring unit and for a drain valve, which are connected to the cavity of the base body, characterized by the features:
• - In the cavity ( 13 ) of the base body ( 11 ), a throttle point ( 24 , 27 , 33 ) is arranged between the connection point for the pressure generator ( 12 ) and the connection point ( 17 ) for the pressure measuring device ( 18 ).

2. Blood pressure meter according to claim 1, with the features:

• the drain valve has its own valve housing,
• - The valve housing is connected to the cavity of the base body between the connection point for the pressure generator and the connection point for the pressure measuring device, characterized by the features:
• - The valve housing ( 37 ) of the drain valve ( 36 ) extends through the cavity ( 13 ) of the base body ( 11 ) and separates the two partial spaces ( 31 , 32 ) from each other,
• - In the region of the cavity ( 13 ) of the base body ( 11 ), the valve housing ( 37 , 38 ) has on its outside a circumferential groove ( 39 ) which is at least partially connected to each of the two sub-spaces ( 31 , 32 ),
• - The valve housing ( 37 , 38 ) has in the region of the circumferential groove ( 39 ) at least one through hole ( 41 , 42 ) which is in communication with the interior of the valve housing ( 37 ).

3. Blood pressure meter according to claim 2, characterized by the features:

• there is a pair of through holes ( 41 ) which are arranged on the valve housing ( 37 , 38 ) at least approximately diametrically to one another,
• - There is preferably a second pair of through holes ( 42 ), which are also arranged at least approximately diametrically with respect to one another and whose alignment line is preferably oriented at right angles to the alignment line of the first pair of through holes ( 41 ).

4. Blood pressure meter according to claim 1, having the features:

• the drain valve has its own valve housing,
• - The valve housing is connected to the cavity of the base body between the connection point for the pressure generator and the connection point for the pressure measuring device, characterized by the features:
• - The valve housing ( 21 , 27 ) of the drain valve ( 19 ) extends through the cavity ( 13 ) of the base body ( 17 ) and separates the two part spaces ( 31 , 32 ) from each other,
• - In the region of the cavity ( 13 ) of the base body ( 11 ), the valve housing ( 27 ) has two through holes ( 33 ) which are connected to the interior of the valve housing ( 37 ),
• - The one through hole ( 33 ) communicates with that sub-space ( 31 ) of the base body ( 11 ) in which the connection point for the pressure generator ( 13 ) and the connection point ( 16 ) for the measuring sleeve are arranged,
• - The other through hole ( 33 ) is connected to that sub-space ( 32 ) of the base body ( 11 ) in which the connection point ( 17 ) for the pressure measuring device ( 18 ) is arranged,
• - In the interior of the valve housing ( 21 ) is at least in the region of the two through holes ( 33 ) a closing spring for the drain valve ( 19 ) in the form of a coil spring ( 24 ), the turns of which are closely adjacent to each other at least in this area of the interior.