|
| 
Get related patents on CD |
| United States Patent | 4248242 |
| Link to this page | http://www.wikipatents.com/4248242.html |
| Inventor(s) | Tamm; Ulf, S. H. (122, chemin de la Montagne, 1224 Chene-Bougeries, Geneva, CH) |
| Abstract | An occlusive sphygomomanometer provides a single control button which
allows a simultaneous modification of the rate of evacuation of air
admitted into an air chamber for occlusion of an artery and the switching
on and off of power to an electronic circuit treating information coming
from a sensing device sensing Korotkoff noises in the artery. |
| |
 |
Title Information  |
|
|
| Inventor |
Tamm; Ulf, S. H. (122, chemin de la Montagne, 1224 Chene-Bougeries, Geneva, CH) |
|
|
|
| Publication Date |
February 3, 1981 |
|
|
|
|
|
| Filing Date |
January 19, 1979 |
|
|
|
|
|
|
|
|
|
|
|
|
|
| Priority Data |
Jan 20, 1978[CH]436788/78 |
|
|
|
|
|
|
|
|
 |
|
 |
Title Information |
|
|
|
Claims |
|
|
What I claim is:
1. An occlusive sphygmomanometer for measuring an arterial blood pressure,
comprising:
an elastic air chamber which is engageable around the arm of a patient to
exert a pressure on an artery of the patient's arm when inflated and
thereby momentarily interrupt the blood circulation in the artery;
a pumping device connectable to the air chamber to inflate the air chamber
by introducing air thereinto;
a manometer connected to the air chamber and indicating the air pressure in
the chamber;
sensor means fixed on the air chamber for sensing the Korotkoff noises
produced in an artery during the systolic phase of a heart beat and having
an output producing a signal in response thereto;
a display device coupled to the sensor means to display the presence of
Korotkoff noises sensed by the sensor means;
an electronic circuit coupling the sensor means output signal to the
display device to amplify the signal and control the display device; and
a control device comprising a rotary manifold valve having a manually
operable rotary element, and switching means for switching on and off
power to the electronic circuit integral with the rotary element, the
rotary manifold valve connecting the air pump to the air chamber through
the rotary element when the element is in a first rotary position, the
rotary manifold valve connecting the air chamber through the rotary
element to the exterior of the valve when the element is in a second
rotary position to provide evacuation of air from the chamber at a slow
rate of speed and the rotary manifold valve connecting the air chamber to
the exterior of the valve through the rotary element when the element is
in a third rotary position to provide evacuation of air from the chamber
at a fast rate of speed greater than the slow rate of speed, and the
switching means respectively switching on and off power to the electronic
circuit when the element is rotated to and from the second position.
2. The sphygmomanometer as claimed in claim 1 in which the electronic
circuit includes a magnetic reed switch connected in series with the power
supply of the circuit and located adjacent the switching means when the
rotary element is in the second position, and the switching means include
a magnet so that when the magnet is adjacent the magnetic reed switch, the
reed switch is closed connecting power to the electronic circuit.
3. The sphygmomanometer as claimed in claim 1 in which the rotary manifold
valve includes a casing having a chamber interior thereof, and having an
input passage connected to the pumping device, an output passage connected
to the air chamber and an exit passage open to the exterior of the casing,
the input, output and exit passages opening into the chamber and the
rotary element being a cylindrical body rotatively mounted in the chamber
and having passages therein for interconnecting said input, output and
exit passages.
4. The sphygmomanometer as claimed in claim 3 in which said rotary element
includes a first passage therethrough connecting the input passage to the
output passage when in the first rotary position to provide connection of
the pumping device to the air chamber.
5. The sphygmomanometer as claimed in claim 4 in which said rotary element
includes a second passage therethrough having a small diameter for at
least a portion thereof, said second passage connecting the output passage
to the exit passage when the element is in the second rotary position to
provide the evacuation of air from the chamber at the slow rate of speed.
6. The sphygmomanometer as claimed in claim 5 in which said rotary element
includes a third passage therethrough having a large diameter greater than
said small diameter for at least a portion thereof, said third passage
connecting the output passage to the exit passage when the element is in
the third rotary position to provide the evacuation of air from the
chamber at the fast rate of speed greater than the slow rate of speed. |
|
|
|
|
|
|
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
The present invention relates to an occlusive sphygmomanometer for
measuring the arterial blood pressure. The device comprises an elastic air
chamber intended to exert a pressure on an artery of a patient, so as to
interrupt momentarily the blood circulation in the artery; a pumping
device allowing the introduction of air into the air chamber; a manometer
indicating the pressure in the chamber; a sensing device for the Korotkoff
noises in the artery; a display device of the presence indicating the
Korotkoff noises; and an electronic circuit controlling the sensing device
and display device.
Such sphygmomanometers are known per se. They have the advantage of being
easier to operate than conventional medical sphygmomanometers used with a
stethoscope and allow patients to by themselves check their arterial blood
pressure.
The purpose of the present invention is to simplify the operation of such
sphygmomanometers so that the patients can use them with a minimum of
training.
SUMMARY OF THE INVENTION
To this effect, the sphygmomanometer according to the invention comprises a
control device ensuring the connection between the pumping device and the
air chamber, and the evacuation of this chamber at two or more different
rates of speed, and, simultaneously, the switching on and the switching
off of the said electronic circuit. This control device comprises a
manifold valve of which a manually operated movable element is integral
with the means for switching on and off the electronic circuit of the
sphygmomanometer.
BRIEF DESCRIPTION OF THE DRAWING
The drawings show, by way of example, one possible variety of the
invention.
FIG. 1 is a diagrammatic perspective view of an occlusive sphygmomanometer.
FIG. 2 is a plan sectional view of a detail, diagrammatically represented,
along line II--II of FIG. 3.
FIG. 3 is a sectional view along line III--III of FIG. 2.
FIG. 4 is a plan sectional view of the same detail, but represented in
another working position, along line IV--IV of FIG. 5.
FIG. 5 is a sectional view along line V--V of FIG. 4.
FIG. 6 is a plan sectional view of the same detail, but represented in a
third working position, along line VI--VI of FIG. 7, and
FIG. 7 is a sectional view along line VII--VII of FIG. 6.
DESCRIPTION OF THE PREFERRED EMBODIMENT
The sphygmomanometer represented comprises a housing 1 having a
parallelepiped general shape, provided with a flexible cuff 2 intended to
be engaged on the arm of a patient. This cuff comprises in its interior an
elastic air chamber diagrammatically represented at 3 in FIG. 3.
The housing 1 is provided with an articulated flap 4 carrying a manometer 5
connected, by a suitable connection, to the air chamber 3 in order to
indicate the pressure within this chamber.
The cuff 2 comprises a sensor device intended to pick up Korotkoff noises,
i.e. noises produced in the arterial wall during the systolic phase of the
patients' heart beat.
The apparatus comprises moreover a display device constituted by a lamp 6
indicating the presence or the absence of the said Korotkoff noises by
lighting up or not, and an electronic circuit, represented by a block 7 of
FIG. 2, which is intended to amplify the signals received by the sensor
device and to control the display device 6. This electronic circuit is
powered by a source of current 8 the terminals of which are connected with
the terminals of the circuit by a lead 9-10 comprising a magnetic reed
switch 11.
The apparatus as disclosed and represented comprises moreover a hand pump
12, diagrammatically represented in FIG. 3, consisting of a rubber bulb
located in a hollow protruding handle 1a of the housing 1. This rubber
bulb can be operated manually.
Such an apparatus is known per se, and has not been disclosed and
represented in detail.
The pump 12 is connected to the air chamber 3 by the intermediary of a
control device represented in detail in FIGS. 2 to 7. This control device
comprises a manifold valve including a hollow casing 13 the inner chamber
of which, designated by 14, is tightly closed by a cover 15 and which is
traversed by a rotative shaft 16 having a fixed control button 17 thereon
which is operable manually. This casing 13 is provided with input and
output passages 18 and 19, opening into the chamber 14 and aligned with
each other. The input passage 18 is connected by a pipe 20 with the
pumping device 12, and the output passage 19 is connected by a pipe 21,
with the air chamber 3. The casing 13 is moreover provided with an exit
passage 22, also opening into the chamber 14, situated opposite a hole 23
provided in the housing 1.
The shaft 16, operable by means of the control button 17 carries and fixed
thereupon, a circular cylindrical body or rotary element 24 tightly
located in the chamber 14. This body 24 is provided with a diametrical
passage 25 (FIG. 3), with a first recessed passage 26 (FIG. 5)
communicating with a passage 27 of an exactly calibrated small diameter
and parallel to the axis of the body 24, and with a second recessed
passage 28 (FIG. 7) communicating with a large passage 29 parallel to the
calibrated passage 27. It is to be noted that the passages 27 and 29 have
been represented in FIGS. 2, 4 and 6, but in dot and dash lines since the
body 24 does not appear in these drawings.
At last, the shaft 16 carries, situated outside the cover 15 closing the
chamber 14, and located in a recess 30 provided in the casing 13, a disc
31 provided with three notches 32, 33 and 34 fitting into a jumping spring
35 secured to the lateral wall of the recess 30 so as to ensure the
stability of the several working positions of the body 24. The disc 31
carries moreover a permanent magnet 36 playing a double role. In one roll
to magnet 36 serves as an abutting member preventing the control button 17
from being rotated beyond its two extreme positions, in the extreme
positions the magnet 36 abuts against either an inner protrusion 13a or
against an inner protrusion 13b, of the lateral wall of the recess 30. In
the other role magnet 36 serves to control, in a working position of the
control device, the switch 11.
The patient engages the cuff 2 on his or her arm with the cuff maintaining
itself elastically on the patient's arm. The patient then brings the
control button 17 into a first position, marked on the housing by
indications not represented in the drawing, corresponding to the position
shown in FIGS. 2 and 3, in which the diametrical passage 25 of the body 24
is aligned with the passages 18 and 19 of the casing 13. However, the
passage 22 of the casing 13 is closed by the body 24. In this position of
the control device, the operation of the pump 12 allows inflation of the
air chamber 3, as indicated by the several arrows 38 of FIG. 3. When a
certain pressure is reached, as indicated by the manometer 5, at which the
circulation of the blood in the artery on which the apparatus acts is
certain to be interrupted, the button 17 is brought into a second working
position (FIGS. 4 and 5). In the second working position, the recessed
passage 26 of the body 24 is situated opposite the passage 19 and its
calibrated passage 27 is situated opposite the passage 22. In this
position of the control device, the air chamber 3 evacuates slowly, as
indicated by the arrows 39 of FIG. 5, the air being able to pass through
the passage 27 only at a very slow rate of speed. In the second working
position of the control device, the permanent magnet 36 is situated in the
vicinity of and controls the closing of the magnetic reed switch 11. A
small bar of soft iron 40 is located in the casing 13 opposite the
abutment 13a, so as to conduct the magnetic field of the magnet 36 in the
direction of the switch 11.
When the switch 11 is closed, the electronic circuit 7 is powered by the
source of current 8 and enters into operation. It produces the lighting of
the lamp 6 as soon as the Korotkoff noises are perceptible in the
compressed artery, i.e. when the blood circulation starts again. The
patient then reads the corresponding pressure on the manometer 5. When the
artery is entirely released, the Korotkoff noises are no longer
perceptible by the sensor so that the lamp 6 is switched off at this time.
The patient also then reads the corresponding pressure on the manometer 5.
When the readings are ended, the patient brings the control device into its
third position, represented in FIGS. 6 and 7, in which the recessed
passage 28 of the body 24 is situated opposite the passage 19 of the
casing 13 and the passage 29, of large section cross, is situated opposite
the passage 22. The passage 29 being of a much greater diameter than the
calibrated passage 27, the air chamber 3 is rapidly deflated, as indicated
by the arrows 41 of FIG. 7. Moreover, in this position, the magnet 36 is
no longer situated opposite the switch 11 so that switch 11 is opened and
the electronic circuit 7 is no longer powered.
* * * * *
|
|
|
|
|
|
|
Description |
|
