DE835782C - Heart rate indicator - Google Patents

Description

Heart rate indicator The subject of the invention provides a pulse indicator which, in contrast to known pulse counters, is made directly by a pointer deflection shows the number of pulses (related to the minute).

The well-known type of pulse measurement is done by touch the artery and counting the pulse beats during a certain time. This requires Attention and focus, and most importantly, it takes time. The through the present invention characterized pulse indicator should be as short as possible Time on a scale with a pointer deflection an accurate reading possibility Offer. But it should also serve as a pulse monitoring device, so that during operations the pulse can be continuously monitored and, if necessary, recorded graphically.

The latter is likely for experimental, observation and research purposes be of particular importance.

The heart rate monitor would mainly be used in hospitals, Clinics etc. as well as the general practitioner offer great advantages.

I) The display device can be through various technical possibilities be solved. It is best to split the pulse indicator into the pulse collector A and that actual display device B, which is placed anywhere away. held in hand or by means of a carrying strap so that the hands are free for other work the neck can be hung.

The pulse pick-up A, which is held on the artery (pressed lightly) or can be tied up for permanent monitoring, consists of one in Fig. 1 Membrane I, which has an air pillow 2 the I) jerk off the artery received, with then a pulsating closing and breaking of the contacts 3 takes place.

Another principle is shown in Fig. 2. An elastic ball 4 in connection with a riser pipe 5 is up to the level of the lowest contact 6 filled with mercury. As soon as a pulse beat on the ball 4, will the electrically conductive liquid is raised slightly and provides the contact 7 via the Connection of the circuit.

One possibility is shown in Fig. 3. Here the pressure of the pulse acts on the coal grains 8, similar to a microphone, and thereby changes the N resistance, this results in a voltage fluctuation which is amplified in the tube 9 and brings the Realais 10 to respond.

The actual display device B now receives the current pulses from the pulse pick-up A and sets it in the pointer deflection using electrical and mechanical functions around. In Fig. 1, a spring drive 11 is required via gear 12 and transmission gear 13 the shaft 14 in rapid rotation. The eddy current driver, which works according to the speedometer principle works and consists of the magnet 15 and driver cap 16, images through the flywheel of the magnet 15 and the eddy current effect in connection with the return spring I7 an (intrinsic moment that keeps the drive system in equilibrium and adjusted to a certain speed. This then corresponds to the full pointer deflection of the goat 18. On the shaft 14 there is still an eddy current disk 19 attached, which is now decelerated by the SIagnet 20 in the rhythm of the pulse. This means, With a fast pulse, the deceleration is greater and therefore the pointer deflection a different one than with a slow pulse beat and thus less braking of the eddy current disc 19. The pulse rates are calibrated on the 21 scale. So special Pointer fluctuations are avoided, the centrifugal mass must be so large that between the individual pulse beats only a small change (acceleration or deceleration) is possible.

This device is unlikely to come up for long-term observation because from time to time the spring drive> 1 1 must be rewound. But this can Spring drive by a small electric motor that comes from a flashlight battery is fed. be replaced.

Fig. 4 shows another display system, where the current pulses synchronously with the pulse rate transmitted to a magnet 22. With every pulse the oscillating armature 23 is tightened. The shaft is via the freewheel gear 24 25 set in rotation. This rotation is now transformed via toothed transmission 26 and brings the flywheel 27, which is mounted on shaft 28, in rapid rotation. After a short time, the flywheel becomes a corresponding to the impact of the oscillating armature 23 Assume constant speed. So that the oscillating armature 23 is always the same Covered the way, the stop 29 is attached. With quickly successive When the pulse beats, the oscillating armature is attracted at shorter intervals, which is why the flywheel 27 will also assume a higher speed than hot in larger ones Pulse beats occurring at intervals. So you just have to put them in accordingly implement a pointer swing. This can again be done in a known manner using the eddy current principle according to Fig. 1 or by flyweight 30 according to Fig. 4. Depending on what proves to be more favorable for the display, the current surge can occur during the pulse or by interposing a closed-circuit relay, the intermittent pulse beats are used will. The device can be made fine mechanically small, so that the display device about the shape and size of a voltmeter.

Claims (2)

PATENT CLAIMS 1. Heart rate indicator, consisting of the heart rate monitor and the display device, characterized in that by means of contact or change the resistance of a carbon granule capsule with an amplifier device every single one Pulse beat causes a current pulse 5, which either directly or via a closed-circuit relay, to exploit the intermediate times, power surges into the display device, which these converted into a pointer deflection by means of electrical and mechanical equipment. which makes it possible to read the direct value of the pulse rate on a calibrated scale. 2. Pulse indicator according to claim I, characterized in that the Current impulses in the display device act on an eddy current magnet, which is driven by a motor Drive rotating system more or less decelerates according to the pulse rate and this deceleration in a known way by means of eddy current drivers or centrifugal force systems converts into a corresponding pointer deflection, or that the current pulse through a strong magnet an anchor in the rhythmic oscillating movements corresponding to the pulse beat offset, which in turn set a drive system in motion and thus one of the Direct display proportional to the pulse rate by means of a pointer deflection.