RU2167600C1 - Apparatus for measuring volume of respired gas in ventilators - Google Patents

Abstract

FIELD: medical equipment. SUBSTANCE: apparatus has lung model (such as pneumatic model) with one outlet joined through connecting member to opening for connecting patient to ventilator and other outlet connected to device for measuring maximum and minimum inhalation pressure. This device is joined with its outlets to measurer of volume of respired gas. Maximum and minimum inhalation pressure measurer has pressure converter 5, amplifier 6, Pmax selection unit and Pmin selection unit. Measurer of volume of respired gas has subtraction unit (Pmax and Pmin), multiplication unit (Pmax and Pmin) x C, lung model extension setter, indicator of value of respired gas volume, and analog-to-digital converter. EFFECT: simplified construction and increased precision in measuring of volume of respired gas. 2 cl, 1 dwg

Description

 The invention relates to medical equipment, and in particular to devices for measuring tidal volume in mechanical ventilation apparatus (IVL), including apparatus with a constant gas flow in the respiratory circuit.

 The invention will find application in the commissioning, tuning and testing of ventilators.

A device for measuring tidal volume using a pneumatic model of the lungs is known, in which extensibility is modeled by compression of gas in a rigid container (L. Randell-Backer, PWThompson, WW Mapleson "Automatic ventilation of the Lungs" Blackwell scientific publication (3-rd edition), 1980 d, chapter "Laborstory Testing of Automatic Ventilators")
Improving the performance of such a model is achieved by providing an adiabatic process of gas compression (DW Hill and V. Moore "The action of adiabatic effects on the complianse of an artificial thorax". British Journal of Anaesthesia, 37, 19, 1965).

 However, the known device for measuring tidal volume is characterized by significant disadvantages.

 In order to measure the tidal volume, it is necessary to introduce a spirometer into the measurement circuit, and in the presence of a continuous flow in the respiratory circuit during inhalation and exhalation, a non-reversing valve. Each of these elements introduces a certain measurement error. In this case, the error introduced by the non-reversible valve cannot be taken into account in advance, since the bypasses in it depend on the quality of assembly of the valve and on the level of pressure in the respiratory circuit in the exhalation phase, which is not equal to 0 with a continuous flow in the respiratory circuit.

 A device is also known for measuring the respiratory volume of lungs in ventilators by measuring the difference between the highest and lowest inspiratory pressures in a lung model. The device for measuring tidal volume contains a pneumatic model of the lungs, one input of which is connected to the patient’s tee, and the other to the means for measuring the highest and lowest inspiratory pressures — an arrow gauge (see International Standard ISO 10651-1, 1993, clause 51.10, figure 1).

Tidal volume is defined as the product of the difference between the highest and lowest inspiratory pressures in the lung model and the extensibility of the lung model:
V _t = ΔP • C,
where V _t - tidal volume;
ΔP is the difference between the highest and lowest inspiratory pressures;
C is the extensibility of the lung model.

 A significant disadvantage of this device is the low accuracy of determining the pressure difference, since it is determined visually from the readings of the gauge. With significant values of the ventilation frequency, this device is practically not suitable for determining the pressure difference due to the fact that the dial gauge has unsatisfactory dynamic characteristics, and, in addition, the visual determination of the peak values of inspiratory pressures introduces a significant element of subjective perception. All this leads to the fact that the measurement error cannot be predetermined, and the measurement time is significantly extended.

 The present invention solves the problem of improving the accuracy and automation of measuring tidal volume during the commissioning and testing of ventilators.

 The solution of the problem is achieved as follows.

 A device for measuring tidal volume in a ventilator, containing a lung model, for example a pneumatic one, one input of which is connected through a connecting element to an opening for attaching a patient to a ventilator, and the other is connected to a means for measuring the highest and lowest inspiratory pressure. .

In this case, the means of measuring the highest and lowest inspiratory pressures is made in the form of a pressure transducer, amplifier, and extraction units P _max and P _min , the output of the pressure transducer is connected to the input of the amplifier, the first and second outputs of which are connected respectively to the input of the allocation unit P _max and the input of the allocation unit R _min The tidal volume calculator contains a subtraction unit (P _max - P _min ), the first and second inputs of which are connected respectively to the output of the allocation unit P _max and the output of the allocation unit P _min . The output of the subtraction unit (P _max - P _min ) is connected to the first input of the multiplication block (P _max - P _min ) • C, the second input of which is connected to the output of the lung model extensibility presenter, and the output through an analog-to-digital converter is connected to the tidal volume indicator .

 The technical result of the present invention is to improve the accuracy of measuring the tidal volume, which allows to improve the quality adjustment and tuning of the ventilator, to obtain reliable data on the supplied tidal volume and to reduce the time of the measurement procedure.

 The invention is illustrated by the description of the device for measuring tidal volume and the drawing, which shows a block diagram of the developed device.

 The tidal volume measuring device contains (see the drawing) a lung model 1 (for example, pneumatic), one output of which through a connecting element (patient's tee, adapter, connector, etc.), in this case, through patient's tee 2, is connected to the hole for connecting the patient to the ventilator, and the other input is connected to a means for measuring the highest and lowest inspiratory pressure 3, which is connected to the tidal volume computer 4 by its outputs.

The means for measuring the highest and lowest inspiratory pressures 3 includes a pressure transducer 5, the output of which is connected to the input of the amplifier 6. The first and second outputs of the amplifier 6 are connected respectively to the inputs of the allocation unit P _max 7 and the allocation unit P _min 8.

The calculator of the tidal volume 4 contains a subtraction unit (P _max - P _min ) 9, which is connected by the first and second input to the output of the allocation unit P _max 7 and the allocation unit P _min 8.

The output of the subtraction unit (P _max -P _min ) 9 is connected to the first input of the multiplication unit (P _max -P _min ) • C 10, the second input of which is connected to the output of the tensile adjuster of the lung model 11. The output of the multiplication unit 10 through an analog-to-digital converter ( ADC) 12 is connected to the tidal volume indicator 13. When measuring the tidal volume, the patient’s tee 2 is connected to the ventilator 14.

 The pneumatic model of the lungs 1 is a sealed metal reservoir, the dimensions of which determine the extensibility of the model. To ensure the adiabatic process of gas compression, the tank is 2/3 filled with material with a high specific heat capacity. Resistance to the airways is represented in a certain way by a porous metal plate. The lung model serves to simulate the patient and is a load for the ventilator (see w-journal "News of medical equipment", VNIIMP, issue 2., M., 1978, pp. 105-108).

 The patient 2 tee is used to connect the pneumatic model of the lungs 1 (as a load) to the ventilator 14.

The tool for measuring the highest and lowest inspiratory pressures 3 provides a measurement with high accuracy of the peak values of inspiratory pressures. The means for measuring the highest and lowest inspiratory pressure 3 comprises:
- pressure transducer 5, which is designed to convert gas pressure to voltage and can be made in the form of a pressure transmitter PDP-1000M (passport for pressure transmitter PDP-1000M tA2.834.008.PS);
- amplifier 6, which is designed to amplify the signal coming from the pressure transducer 5, and can be implemented according to the well-known scheme (Graham. Design and use of operational amplifiers. "Mir", M., 1974, p. 227).

- the allocation unit 7 provides the determination of the maximum voltage value at the output of the amplifier 6 and can be performed according to the well-known scheme ("Electronic circuits and devices", Bystrov Yu.A., Mironenko I.G., ed. "Higher School". M., 1989, pp. 119-120, Fig. 6.7.);
- the selection unit 8 provides the determination of the minimum voltage value at the output of the amplifier 6 and can be implemented according to the well-known scheme (see the book by Bystrov Yu. A., Mironenko I.G. "Electronic circuits and devices", pp. 119-120, Fig. 6.7.).

The tidal volume 4 calculator automatically calculates the tidal volume and visualizes the obtained value on the indicator 13. The tidal volume 4 calculator contains:
- subtraction unit 9, which provides the determination of the difference between the two voltage values and can be performed, for example, in the form of a differential amplifier according to a known scheme (Graham. Design and use of operational amplifiers. "Mir", M., 1974);
- the multiplication unit 10 serves to multiply the obtained difference between the highest and lowest inspiratory pressures by a constant coefficient (C) corresponding to the extensibility (C) of the lung model, and can be implemented on an operational amplifier according to a known scheme (Graham. Design and use of operational amplifiers, " World ", M., 1974, p. 291);
- adjuster of the tensile value 11 is used to enter into the multiplication unit 10 the coefficient of tensile value (C) of the lung model and can be implemented on the basis of variable resistance, which determines the transmission coefficient of the operational amplifier (Graham. Design and use of operational amplifiers. "Mir", M., 1974, p. 224);
- ADC 12 provides the conversion of an analog signal to digital and is made in the form of a separate integrated circuit (Graham. Design and use of operational amplifiers. "Mir"., M., 1974, p. 368);
- the indicator 13 of the value of the tidal volume provides a visualization of the value of the tidal volume and can be performed on the basis of seven LED segment indicators (Kingbright catalog, 1998).

 The measurement of tidal volume is as follows.

One input of the pneumatic model of the lungs 1 using a connecting element - the tee of the patient 2 is connected to the hole for attaching the patient to the ventilator. The other input of the lung model is connected to the input of the means for measuring the highest and lowest inspiratory pressures 3. In the inspiratory phase in the pressure transducer 5, the pneumatic signal is converted into an analog electric signal and fed to amplifier 6. The amplified signal is fed to the inputs of block 7, which emits the maximum inspiratory pressure P _max , and block 8, which releases a minimum inspiratory pressure P _min . The corresponding signals are fed to the first and second inputs of the subtraction unit 9 of the tidal volume calculator 4. In block 9, a difference signal is generated (P _max - P _min ). This signal is fed to the first input of the multiplication unit 10, to the second input of which a constant coefficient corresponding to the extensibility (C) of the lung model is introduced from block 11. The signal corresponding to the product (P _max - P _min ) • C is fed to the input of an analog-to-digital converter (ADC) 12, at the output of which an indicator 13 is installed, where the tidal volume is displayed.

 The developed measuring device allows to obtain automatically and with high accuracy the parameters of the respiratory volume of ventilators, which ensures high quality adjustment and configuration of ventilators of various modifications.

Claims (1)

A device for measuring tidal volume in mechanical ventilation apparatuses containing a lung model, for example a pneumatic one, one input of which is connected through a connecting element to an opening for attaching a patient to a mechanical ventilation apparatus, and the other is connected to means for measuring the highest and lowest inspiratory pressure, characterized in that the device is equipped with a tidal volume calculator, while the means for measuring the highest and lowest inspiratory pressure is made in the form of a transform a pressure generator, an amplifier, and extraction units P _max and P _min , the output of the pressure transducer is connected to an amplifier input, the first and second outputs of which are connected respectively to the input of the allocation unit P _max and the input of the allocation unit P _min , and the tidal volume calculator contains a subtraction unit (P _max - P _min ), the first and second inputs of which are connected respectively to the output of the allocation unit P _max and the output of the allocation unit P _min , the output of the subtraction unit (P _max - P _min ) is connected to the first input of the multiplication unit (P _max - R _min ) x C, where C is constant constant factor corresponding to the value in lung model, a second input of multiplier connected to the output setpoint in lung model, and output through analog-to-digital converter connected to the indicator value of tidal volume.