SU104093A1 - Device for determining and automatically recording blood oxygen saturation - Google Patents

Description

The CinncbiBaeivibiii device is designed for continuous automatic regnastratsi nacycene blood process to; 1C. | Orodom. The device records and shows the percentage of oxyhemog. Iubnna in the arterial blood with respect to the entire g-e MO globin.

The block diagram of the set is given in FIG. , and in principle.: on the scheman of FIG. 2

The princp of the work of D) of the written oxyge.mograf is as follows. The sensor 1 of the device touches the auricle of the test. The sensor signals are associated with a voltage, reduced. 1.are: .1m from measurement circuit 2, are amplified. The tube amplifier 3 is fed to the reversible motor 4. The motor axis is connected to the reichord slider, interleaving the scale indicator and stylus 5. Under the pen, extends the paper roll, which continuously records the sensor signals, is a function of increasing oxygenation of the blood. The scale indicator simultaneously shows the measured value.

Oxy.hemogra.g.r can jia6oTaTb one1 with a multi-sensor with a hand-held auto-somophome; t; cheskogo re key those. I

The device determines, in absolute units, the filling of the blood with an acidor and the content of hemoglobin) bin in c) oi when working with cuvettes. N last case the device works like a heme.) globnometer.

Sensor SOSTOI1 of two miniature cases, soy; 1, 1; 1: a flat spring. In one case, a small electrical cable is installed in the TSAA-1b (cars .1pa), in a fugue-photos-temperent and snootofi.chtry. From the available range of photocells, the most convenient one is used. Le d, if rerencyate noe selenium FZtoelemenga with a barrier layer or use two photocells with a barrier layer, one of which is selenium, and the other is silver-silver. In the first case, a color filter of a UFS-3 color glass is used; in the second, infrared filters.

To examine the cell in the cuvette, the sensor provides the ability to change the distance between the photocell and the illuminator by an amount equal to the width of the cuvette. In addition, it is possible to use a sensor, especially with specially designed for working with cuvettes, in which there are guides for precise installation of a cuvette of predetermined size.

Developed by photovoltaic cells d. measured by the zero method by compensation or by comparing two voltages: one measured and second taken from the measuring circuit. The inequality of these voltages is marked by a zero indicator, made in the form of an electronic amplifier, the output of which includes a reversible motor, moving the reohord slider of the measuring circuit towards the equilibrium circuit, i.e., until two voltages are equal. The slide motor is mechanically connected with the pointer to the scals and pen of the recording device. The instrument scale is graduated directly in units of measurable quantities. The recording device pen moves along a chart tape that moves at a constant speed. The tape is driven by a Warren engine.

The measurement and recording process is carried out continuously and automatically. The measuring circuit of the cathode oximeograph is a potentiometric bridge circuit. E. D.S., developed by photocells, is switched on with voltage Up, taken from the measuring circuit of the device, i.e., is compensated by voltage Up. In case of equality to the input of the amplifier, the signal is not given, since Au:: silt - Y – O and the engine will be stationary, and consequently, the engine of the reichord connected mechanically to the engine will be stationary. If e. d. we develop photocells, and the voltage taken from the measuring circuit of the device is not equal, i.e., and, Up and Di and. -Up - 0, then the amplifier will be fed to the input

iair / unbalance AU, which is the voltage of the standing) voltage.

The unbalance voltage AU is amplified either by a DC amplifier, as is the case, for example, in a cathode oximesometer, or by amplification of the fermenter current. In the case of using an AC amplifier, the signal applied to the input of the amplifier must be appropriately converted, for which there are various ways. This device uses a slightly modified AC amplifier used in electronic recorders. At the input of the amplifier there is a vibration transducer, which converts the voltage of a constant current to an alternating current voltage of 50 hertz.

The AC voltage obtained after the vibration converter, with a frequency of 50 Hertz, is fed to the input of the electronic amplifier. The electronic amplifier consists of two double triodes of type 6Н9 and two double triodes of type 6Н7. The unbalance voltage supplied after conversion to the input of the amplifier is amplified by three stages of voltage amplification, collected according to a rheostat circuit on three triodes of 6Н9 lamps. A single triode of the 6NE lamp is used as a half-wave rectifier to power the anode circuits of the voltage amplifier.

The unbalance voltage, amplified by three stages of voltage gain, is applied to a power stage, which is also a phase-sensitive stage. In the power cascade there are two 6H7 lamps, included in parallel. The anodes of each lamp are supplied with an alternating current voltage of 50 hertz, and the voltage applied to the two anodes of the same lamp is 180 degrees out of phase.

At the output of the amplifier, a reversible asynchronous capacitor-type motor is turned on. Dvngatel has two windings, one connected to the output of the amplifier, and the second connected through a capacitor to the AC circuit, with a frequency of 50 hertz. Depending on which voltage is higher - and Up, current will flow through the right or left triode of the 6Н7 lamp. Depending on the nature of the imbalance, the reversing motor will rotate clockwise or counterclockwise and, consequently, move the slider and the mechanically connected scale indicator and stylus. The movement will occur in the direction of balance until U.v is equal to Up.

Subject invention

Claims (4)

1. A device for determining and automatically recording blood oxygen saturation, consisting of a photoelectric sensor and a recording device, characterized in that, in order to simplify the device and its use in various conditions (for example, when measuring), a zero indicator is used in the device the form of an amplifier, at the output of which a reversing motor is turned on, which moves the reichord engine until reaching a balanced circuit. 2. The apparatus according to claim 1, characterized in that it is provided with a switch for alternately connecting several sensors thereto. 3. The use in the device of claim 1 and 2 of a sensor adapted to set up a blood cuvette in order to determine the absolute values of blood oxygen saturation and the amount of hemoglobin in the blood. 4. A device according to claim 1 and 2, characterized in that a full-wave rectifier is used to power the measuring circuit. The priority according to p. 4 -28 1952 № 104093 - 4 FIG. one v