RU2406543C2 - Method of gas component feeding, device and apparatus for feeding inhalation narcosis - Google Patents

Abstract

FIELD: medical technics.

SUBSTANCE: according to the method, constant volumetric gas speed value is sustained at the level of maximum component volume required for inhalation narcosis per time unit. Adjustment is performed by a lock-type adjustment unit, the effect of which is reduction of gas component feeding time at a given volumetric speed to the calculated value defined by ratio of requested volume to the maximum. To sustain constant gas component feeding, the adjustment is performed by algorithm, with metering feeding time into equal impulses evenly distributed through a time unit. Total time is equal to the calculated value. The invention describes a device for gas component feeding during inhalation narcosis and an inhalation narcosis apparatus for implementation of the method.

EFFECT: minimisation of gas component feeding error.

8 cl, 4 dwg

Description

The invention relates to medicine, and more specifically relates to a method for supplying gas components, a device and apparatus for delivering inhaled anesthesia.

A known method for the automatic supply of gas components during anesthesia to a patient (US patent 6830047, MKI A61M 16/00, 2004), in which using the model calculate the concentration of active gas components (anesthetics) in the patient’s body, compare them with previous information from the database, their difference is calculated, and the concentration is determined by the difference obtained by feeding the component.

A known method and device for supplying an anesthetic (US patent 5806513, MKI A61M 16 / 01.1998), in which the effective control is carried out by a computer that provides a signal to the regulating authority for the supply of gas flow.

The closest is the known method of supplying gas flows during inhalation anesthesia, in which the regulation and measurement of the flow rate and quantity of the gas component are carried out. The flow rate and the amount of the gas component are controlled by a control valve installed at the inlet of the gas supply line by changing the bore (RF No. 2178314 C1, MKI A61M 16/01, 2002, RF patent No. 2248225 C2, MKI A61M 16/01, A. I. Trushin, V. M. Yurevich. Inhalation anesthesia apparatus, M., Medicine, 1989, p. 17).

A known dosimeter of gaseous xenon for anesthesia apparatus (RF patent No. 22422825, A61M 16/01, 2005), designed to regulate and measure the flow rate and amount of gaseous xenon, which is fed into the respiratory circuit of the anesthesia apparatus. The dosimeter contains a measuring device with input and output nozzles and an electronic signal processing unit. Regulation is carried out by a control valve mounted on the inlet pipe.

The closest technical solution is devices for delivering inhalation anesthesia (A.I. Trushin, V.M. Yurevich. Inhalation anesthesia devices, M., Medicine, 1989, p.17), containing their own supply lines for each gas component of inhalation anesthesia, equipped with its own control device in the form of a valve, and a measuring device, which is used as a rotameter or a group of rotameters. The lines are connected by exits to the collector for mixing the components necessary for inhalation and the formation of a further gas stream of an averaged composition, which enters the patient.

The feed control is carried out by changing, on assignment, the volumetric speed due to the action of the control valve on the area of the bore. The task is formed according to the readings of the rotameter. Absolute error (l / min, dm ³ / min) is permissible for rotameter indications, the value of which is defined as the margin of permissible error at the upper limit of measurement (GOST 18856-81, Inhalation anesthesia and mechanical ventilation apparatus. General technical requirements, page 6) .

A separate rotameter has a small operating range, so there is a need, to ensure the full operational range, to sequentially install several rotameters with overlapping ranges (to different measurement limits). This leads to an increase in the permissible absolute error due to the growth of the upper limit of measurement, and, therefore, increases the control error.

With small amounts, especially approaching the lower limit of the gas component supply during inhalation anesthesia, the absolute measurement error becomes at least commensurate with the gas component supply amount, which essentially blocks the regulation process.

The problem of achieving accuracy (reducing the error) of the supply is due to the fact that the level of concentration of anesthetic in the brain tissue must be adequate to the patient's condition during all phases of surgery. This requires multiple control of the supply of gas (s) component (s) during inhalation anesthesia in a wide range of current (working) values during the operation.

The error with each regulatory action, especially at low feed rates, can lead to the supply of a gas anesthetic in an amount inadequate to the patient's condition, thereby worsening his condition and complicating the course of the operation.

The problem of supplying gas components with high accuracy has become especially urgent in connection with the use of modern potent anesthetic drugs, which are administered in small quantities and which, in addition, are environmentally harmful products and expensive drugs. During the operation, for example, the flow rate of an anesthetic such as xenon can be from 20 to 6000 ml / min, the supply of oxygen or nitrous oxide - from 100 to 10000 ml / min.

The basis of the invention is the task of ensuring the supply of gas components with high accuracy by minimizing the control error over the entire operating range of the quantities of gas components supplied.

EFFECT: minimization of the error of regulation over the entire operational range of values of the quantities of the supplied gas component due to the implementation of regulation by supplying the amount of the gas component in time.

The problem is solved in that in the method of supplying the gas component during inhalation anesthesia, in which the gas component is supplied at a volumetric rate, the amount of the gas component supplied per unit time is regulated by a regulatory body located in the supply line to ensure the quantity specified by the patient’s condition , the value of the volumetric velocity is kept constant at the level of the value of the maximum amount of this component required for inhalation anesthesia per unit time, they are controlled by a regulating body of a shut-off type, the controlled action of which reduces the gas component supply time with a constant volumetric rate maintained to a design value determined by the ratio of the set quantity to the maximum value, while to ensure uniform gas component supply, the effect is carried out according to the algorithm, dosing the supply time with pulses of equal duration and uniformly distributed in unit time with step H, while the total pulse duration is equal to the calculated value.

The problem is also solved by the fact that in the device for supplying the gas component during inhalation anesthesia, containing a regulatory body located in the gas component supply line, a shut-off type regulatory body is used and an additional device for stabilizing the gas component volumetric velocity at the maximum value set on the line along the flow, and a timer for generating a signal of controlled pulse action according to the algorithm for supplying the gas component with pulses of equal length elnosti and uniformly distributed in a unit time step h is not less than 0.25 seconds, the timer output is connected with the regulator.

It is preferable to use a solenoid valve as the regulating element of the shut-off type.

It is advisable that the device for stabilizing the volumetric velocity of the gas component at the maximum value would be made in the form of a reducer and throttle calibrated to the maximum value, sequentially installed along the gas stream.

The problem is solved, in addition, by the fact that in the apparatus for delivering inhalation anesthesia, which contains its own supply lines for each gas component of inhalation anesthesia, equipped with its own regulatory body and connected to the outputs for mixing the components, each line has a shut-off type regulatory body and further comprises a device stabilization of the volumetric velocity of the gas component at the maximum value set on the line along the flow, and at least one timer for forming signal of controlled pulse action according to the algorithm for supplying the gas component with pulses of equal duration and evenly distributed in a unit of time with a step H of at least 0.25 seconds, and the timer output is connected with the regulatory body.

It is advisable that an electromagnetic valve be used in the apparatus as the regulating body of the shut-off type.

It is also advisable that in the apparatus the device for stabilizing the volumetric velocity of the gas component at the maximum value would be made in the form of a reducer and an inductor calibrated to the maximum value, sequentially installed along the gas flow.

The apparatus may include a pressure meter installed at the inlet of the gas component supply line.

The invention is further illustrated by the description and drawings, where figa-1C illustrate the implementation of the method of supplying a gas component according to the invention.

2a-2c illustrate an embodiment of a method for supplying a gas component according to the invention (continued).

Fig.2d illustrates the errors of the regulatory process.

Figure 3 shows a schematic diagram of a control device according to the invention.

Figure 4 shows a schematic diagram of an apparatus for delivering inhalation anesthesia according to the invention.

The method of supplying the gas component according to the invention is as follows.

The volumetric feed rate of the gas component is calibrated at the level of V _max (Fig. 1a), equal to the maximum quantity W _{max of} this component, which is necessary for inhalation anesthesia per unit time, for example, a minute. Graphically, W _max represents the area bounded by V _max and unit time boundaries.

In case of inhalation anesthesia, the amount of W _{g of the} gas component is set, which must be supplied per unit time based on the current condition of the patient, and the value of the time T _{p of} supplying a given amount of W _z with a constant volume velocity V _{max is} calculated. For the calculation, the ratio T _p = W _{s is used.} / V _max (graphically T _p shown in figa).

The gas component is supplied by acting by the regulating body of the shut-off type according to the algorithm, dosing the supply time with pulses of equal duration and uniformly distributed per unit time, to ensure uniformity in the supply of the gas component. In this case, the total pulse duration is equal to the calculated T _p .

To ensure equal pulse durations, the calculated time value T _{p is} divided by an integer "n" (fig.1b). The obtained value of T _pn equal to T _pn = T _p / n corresponds to the duration of the feed pulse of the gas component. Impulses are evenly distributed in a unit of time (minute). With a uniform distribution, the pulses are discretized in a unit of time with a step H of at least 0.25 seconds, as shown, for example, in Fig. 1c.

During the pulse, the shut-off element passes the gas component with a fully open passage section. In the absence of an impulse, the passage section is completely closed and there is no gas component supply (supply cut-off).

Examples of the supply of various amounts of W ₃ gas component during inhalation anesthesia according to the algorithm according to the invention are shown in FIGS. 2a-2c.

If the predetermined amount W _s decreases, then the calculated time value T _p and the pulse duration T _pn decrease.

The uniform distribution of pulses per unit time in this case takes the form shown in figa, or figv, or figs.

Thus, a predetermined amount of W _{g of a} gas component is supplied in doses of equal volume with a total number of doses n per unit time (minute). The quantity q of the gas component supplied at a dose q = W _s / n. The total (volume) amount of the supplied gas component during the time T _p : W _s = T _pn · nV _max .

The error in the supply of the gas component is determined by the error (T _pn · n V _max ) ¹ , and at V _max = const and n = const it is determined by the error of time control and the error of the transient process when the inertia of the valve closure takes place. As is well known, the errors of time regulation are extremely small.

Transient errors (inertia of valve closure) remain, which are illustrated by blackened areas in Fig.2d.

The error is the same in absolute value over the entire operating range of the quantities of the supplied gas components.

A device for supplying a gas component during inhalation anesthesia (Fig. 3) contains a shut-off type regulator 1 located in the gas component supply line 2, a timer 3 for generating a time-controlled pulse signal, the output of which is connected with the regulator 1, and at the input 4 the value of the set quantity W _{s of the} gas component is supplied, the device 5 for stabilizing the space velocity of the gas component at the level of the maximum value V _max .

The timer 3 contains a diagram of the algorithm for effecting the regulatory body 1, dosing the exposure time with pulses of equal duration and uniformly distributed per unit time, according to the invention.

As the regulatory body 1 use an electromagnetic valve.

The stabilization device 5 contains a gear 6 and a throttle 7, sequentially installed along the gas flow in line 2. The throttle 7 is calibrated to a maximum V _max .

The device operates as follows.

Preliminarily, using the reducer 6 and throttle 7, the volumetric feed rate of the gas component in line 2 is calibrated at the level of V _max equal to the maximum amount W _{max of} this component required during inhalation anesthesia per unit time (minute).

When the device is running, the timer 3 is set to the value of the amount W _{3 of the} gas component. Timer 3 calculates the time T _p and the pulse duration T _pn and sequentially sends signals of duration T _pn to the regulator 1, evenly discretizing them according to the algorithm with step N.

Upon receipt of the signal, the regulatory body 1 is fully open and supplies the gas stream with a value of V _max for T _pn . In the absence of a signal, the regulatory body 1 is completely closed.

The apparatus for supplying inhalation anesthesia (Fig. 4) contains shutoff type regulating organs 1 located in their own supply lines 2 for each gas component, connected by outputs 8 for mixing the components, a timer 3 for generating time-controlled pulsed signals on the regulating organ 1 of each gas component.

At the input of timer 3, the values of the set quantity W _s ^{m of} each gas component are received (m = 1, 2, etc.). The outputs of the timer 3 are connected with the regulatory bodies 1, respectively, of the component.

The timer 3 contains a diagram of the algorithm for effecting the regulatory bodies 1, dosing the exposure time with pulses of equal duration and evenly distributed in a unit time of each component.

4 shows one set timer 3. However, if necessary, other timers can be set, for example, separately for each component.

As the regulatory body 1 use an electromagnetic valve.

The stabilization device for the space velocity of each supply line 2 contains a reducer 6 and a throttle 7, sequentially installed along the gas flow in line 2. The throttle 7 in each line 2 is calibrated to its own maximum value V _max ^m .

The device may contain at the outlet 8 a bag-receiver (not shown) for additional smoothing of pulsations and averaging of the composition.

The apparatus may comprise a pressure sensor 9 mounted on a flow supply line to a gas component supply device for monitoring pressure.

Figure 4 shows a schematic diagram of an apparatus for inhalation anesthesia containing its own supply lines of three gas components - oxygen O ₂ (m = 1), nitrous oxide NO ₂ (m = 2) and xenon Xe (m = 3).

The device operates as follows.

Preliminarily, using the reducer 6 and throttle 7, the volumetric feed rate of each gas component in its own line 2 is calibrated at the level of V _max ^m equal to the maximum amount W _max ^{m of} this component required during inhalation anesthesia per unit time (minute).

During operation, timer 3 is set to the value of the amount W _s ^{m of} each gas component. Timer 3 calculates the time T _p ^m and the pulse duration T _pn ^m and provides the corresponding signals to the regulator 1, respectively, of the gas component, evenly discretizing them with a step of H ^m .

Upon receipt of the signal, the regulatory body 1 is fully open and supplies a gas stream with a value of V _max ^m for T _pn ^m . In the absence of a signal, the regulatory body 1 is completely closed.

The present invention can be used in medicine for inhalation anesthesia.

Claims (8)

1. The method of supplying the gas component during inhalation anesthesia, in which the gas component is supplied at a volumetric rate, the amount of the gas component supplied per unit time is regulated by a regulatory body located in the supply line to ensure the quantity set according to the patient’s condition, characterized in that the value of the volumetric velocity is kept constant at the level of the maximum amount of this component required for inhalation anesthesia per unit time, regulation is carried out by regulatory m shut-off type organ, the controlled action of which reduces the gas component supply time with a constant constant volume velocity to a calculated value determined by the ratio of the set quantity to the maximum value, while to ensure uniform gas component supply, the effect is carried out according to the algorithm, dosing the supply time with pulses of equal duration and evenly distributed in unit time, while the total pulse duration is equal to the calculated value. 2. A device for supplying a gas component during inhalation anesthesia, containing a regulatory body located in the supply line of the gas component, characterized in that it uses a shut-off type regulatory body and additionally introduces a device for stabilizing the volumetric velocity of the gas component at the maximum value set on the line along the flow, and a timer for generating a signal of controlled pulse action according to the algorithm for supplying the gas component with pulses of equal duration and equal evenly distributed and in unit time, with a step H of at least 0.25 s, and the timer output is connected with the regulatory body. 3. The device according to claim 2, characterized in that the solenoid valve is used as the regulating body of the shut-off type. 4. The device according to claim 2, characterized in that the device for stabilizing the volumetric velocity of the gas component at the maximum value level is made in the form of a reducer and an inductor calibrated to the maximum value, sequentially installed along the gas stream. 5. Apparatus for supplying inhalation anesthesia, containing its own supply lines for each gas component of inhalation anesthesia, equipped with its own regulatory body, and connected by outputs for mixing components, characterized in that each line has a regulating body of a shut-off type and further comprises a device for stabilizing the gas volumetric velocity component at the maximum value level, installed on the line in the direction of flow, and at least one timer for generating adjustable signals pulse impact on the algorithm supply gas component pulses of equal duration and uniformly distributed in a unit time step h is not less than 0.25 sec, the timer output is connected with the regulator. 6. The apparatus according to claim 5, characterized in that the solenoid valve is used as the regulating body of the shut-off type. 7. The apparatus according to claim 5, characterized in that the device for stabilizing the volumetric velocity of the gas component at the maximum value is made in the form of a reducer and an inductor calibrated to the maximum value, sequentially installed along the gas stream. 8. The apparatus according to claim 5, characterized in that it comprises a pressure meter installed at the inlet of the gas component supply line.