PL183237B1 - Piston-type simulator of mechanical lung properties - Google Patents

Abstract

A piston simulator of the mechanical properties of the lungs comprising a pneumatic cylinder with a piston connected via an electric motor to a piston speed control system comprising piston speed and displacement transducers connected to a controller located at the input of the electric motor, further comprising a pressure transducer connected to the input channel of the cylinder, characterised in that the electric output of the pressure transducer (10) is connected to the input (17) of the conversion block (15), the output of which is connected to the control input of the controller (6)

Description

The subject of the invention is a piston simulator of the mechanical properties of the lungs intended for teaching purposes, such as training devices for medical personnel, and for research purposes related to the construction and evaluation of the operation of devices for artificial lung ventilation.

Various solutions of devices for simulating the mechanical properties of the lungs are known. They are generally constructed as mechanical devices consisting of air bellows or pistons, springs, air resistors and sometimes actuators to simulate the patient's natural breathing.

The main disadvantage of all lung mechanical properties simulators built so far is their structural inflexibility associated with the technically very troublesome necessity to build precise, repeatable mechanical elements, such as pneumatic resistors, springs of variable stiffness, force generators and other similar elements.

There is a known model of the viscoelastic properties of the lungs, which is a combination of a laminar flow pneumatic resistor with the chamber of an electromechanical pneumatic condenser. The input of the model is the inlet channel of the pneumatic resistor. The electromechanical capacitor is built in the form of a pneumatic cylinder with a piston moving inside, driven by an electric motor. The displacement of the piston is set by means of the control system as proportional to the pressure in the cylinder chamber, i.e. the entire electric drive system acts as a spring giving the piston displacement proportional to the pressure in the chamber and thus the force acting on the piston.

The advantages of this solution include, first of all, the possibility of a smooth and arbitrary change of the capacity (compliance) of a pneumatic condenser and the possibility of simulating spontaneous breathing by setting an additional piston displacement overlapping its movement caused, for example, by the air flow forced by the respirator attached to the model.

The disadvantages of the model include, first of all, the inability to smoothly change the resistance value and the practical impracticability of simulating the viscoelastic properties of the lungs, which would require the model to be expanded with additional electromechanical elements.

According to the invention, a piston simulator of the mechanical properties of the lungs comprising a pneumatic cylinder with a piston connected via an electric motor to a piston speed control system comprising speed and piston offsets transducers connected to a controller at the inlet of the electric motor, and further comprising a pressure transducer connected to the inlet channel cylinder, characterized in that the electrical output of the pressure transducer is connected to the input of the conversion block, the output of which is connected to the control input of the controller.

In a preferred embodiment, the conversion block comprises an input voltage-current converter, the output of which is connected to the input of the isolating amplifier and to the input of the gyrator loaded with the electric network.

In another preferred embodiment, the conversion block comprises an input analog-to-digital converter connected to a digital input of a computer, the output of which is connected to a digital-to-analog converter at the output of the conversion block.

The simulator according to the invention does not contain such mechanical elements as springs and pneumatic capacitors and resistors, which require very precise execution and whose parameters change is associated with a large design complication.

The degree of complication of the lung model implemented by the simulator according to the invention can be any, and the accuracy of the simulation is limited only by the accuracy of the elements of typical measuring transducers used and by the transmission band of the piston motion control system.

The subject of the invention is explained in more detail in the embodiment in the drawing, in which Fig. 1 shows a diagram of the piston simulator of the mechanical properties of the lungs, Fig. 2 schematically the conversion block of this simulator, Fig. 3 - another embodiment of the conversion block, Fig. 4 - electrical analog of the simulator according to the invention, fig. 5 - part of the circuit of the conversion block from fig. 2, and fig. 6 - its electrical analog, fig. 7 - another example of a part of the conversion block, fig. 8 - its electrical analog, and fig. 9 - an example a simplified network describing the mechanical properties of the lungs.

The piston simulator of the mechanical properties of the lungs comprises a pneumatic cylinder 1 by a piston 2 connected via an electric motor 4 to a piston speed control system comprising a speed transducer 7 and a piston displacement transducer 5 connected to a controller 6 at the input of the electric motor 4, further comprising a pressure transducer 10 connected to through the input channel 11 of cylinder 1. The electrical output of the pressure transducer 10 is connected to the input 17 of the conversion block 15, the output of which is connected to the control input of the controller 6.

The conversion block 15 comprises at the input a voltage-current converter 9, the output of which is connected to the input of the isolating amplifier 8 and to the input of the gyrator 12 loaded with an electric network 13 composed of RLC elements and controlled electrical sources. At the input of gyrator 12 there is voltage u _s and current flows i _s i. The output parameters of gyrator 12 and the input network 13 are current i _S 2 and voltage u _S 2

In another example, the conversion block 15 includes an input AC analog-to-digital converter connected to a digital input of the computer 18, the output of which is connected to a digital-to-analog converter at the output 16 of the conversion block 15.

The digital signal from the output of the AC analog-to-digital converter is fed to the digital input of the computer 18 and is at the same time the input signal for the system of electric network equations with a given impedance, numerically solved in the computer, where the solution of the network equation is the voltage that is obtained in digital form by a digital-to-analog converter CA to an analog signal supplied to the output terminal 16 of the conversion block 15.

The input channel 11 of cylinder 1 is the input channel of the simulator. The pressure p in this channel and the gas flow rate q flowing into the cylinder chamber of volume V are inputs to the simulator corresponding to the pressure and flow rate in the patient's trachea. The starting position xo of the piston 2 as it moves in cylinder 1 corresponds to the average volume of the patient's upper airways. The piston is driven by a lead screw 3 associated with the shaft of the electric motor 4.

The 5 piston position and 7 speed electric transducers provide feedback signals to the controller 6 which acts as a regulator of the piston 2 travel speed.

183 237 a typical servo-control system that keeps the piston speed v proportional to the controller setpoint Uv provided by the conversion block 15.

The simulator according to the invention shown in Fig. 1 is equivalent to the system shown in Fig. 2, in which the pneumatic impedance Zp is connected to the pneumatic terminal 11, in which the pressure p and the gas flowing q is connected:

Zp = Z _m / A ² Z _m = F / V where: F - force acting on the piston, A - piston surface.

In parallel with the pneumatic impedance, a pneumatic capacitor with a capacity of C _v is connected:

C _v = V / e.g. _a where: n - polytrope exponent, p _a - atmospheric pressure, V - chamber volume V = x ₀ A

Uo and o with symbolically marked values of instantaneous voltages and currents generated by the controlled voltage source of the RLC network.

Figure 5 shows part of the simulator circuit of Figure 1 related to the RLC network 13 in the gyratory version. The presence of a gyrator 12 causes the input impedance Z _e (Fig. 6) to be directly proportional to the pneumatic impedance Z _p i with the proportionality coefficient kf

Zpi ki ^_ With _e

It is also possible to fail to simulate a complete gyrator. Pokacane is jnsż mt fic. 7, where the RLC network 13 is directly connected as a load of the current source 9. This solution is, however, less convenient, because the network impedance is mapped to the same value as from (Fig. 8), i.e. == im. with _e gdeie: k - cemeterial) Jy k pjopozcjonalnośei

In my case, the mapped cavernry network has a stable euolar force to describe an analogous pneumatic network! alum.

On the fiśr- d poZazanaj ^ bzzyżlaOowz unraaaczona s iem ορίϋΐρ ^^ ι wia $ on the mechanisms of the lungs.

The pneumatic part of the second lung presented the kdt in the form of the inductance L _p and simulating the inductance of the lung, in the tubular cavities, rczzrtanaii R _pa oymuiujacei saeaty lzaabtiowe pzzfluxes. connensaOoea compiling his connoisseur of gan ^ yob doge reminiscent of the ^l zp'ch cpo and the condenrotic of an embarrassing ρι ^ ι ^ι ^ ί C _pW żOdortałaS to someone's pitcher.

C ^ ęś Cackowlj ipiua language presented in jpytaoi rzeregsweao the following jazz tone () L _m , R _m . C _{m ra} c _aa showing tissue inertia and elasticity as well as a certain resistance to viscous losses in the lung tissue structure. (Ζ ^ ΐ2ε = η1 / π lż _and sin t represents the source of the spontaneous breath ganeIΌwanabo proez minrnia skeletal. The dynamic properties presented on fiż- 9 RLw from \\ p: orowgwmn wki ^ pc and imedance ρ ^ Ί-ΡαΙχ-Όζη! in the voivodship towards ss- _o mulator, poopżkclłżlnai to η ^ εΡΗ !!!! wgJStiowćj network.

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Fig. 3

Fig. 4

Fig. 5

Fig. 6

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Fig. 9

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Publishing Department of the UP RP. Circulation of 50 copies. Price PLN 2.00.

Claims (3)

Patent claims 1. A piston simulator of the mechanical properties of the lungs comprising a pneumatic cylinder with a piston connected via an electric motor to a piston speed control system including speed and offsets transducers connected to a controller at the inlet of the electric motor, further comprising a pressure transducer connected to the cylinder inlet channel, characterized by that the electrical output of the pressure transducer (10) is connected to the input (17) of the conversion block (15), the output of which is connected to the control input of the controller (6). 2. The simulator according to p. A device according to claim 1, characterized in that the conversion unit (15) comprises an input voltage-current converter (9), the output of which is connected to the input of the isolating amplifier (8) and to the input of the gyrator (12) loaded with the mains (13). 3. The simulator according to p. The method of claim 1, characterized in that the conversion block (15) comprises an input analog-to-digital converter (AC) connected to a digital input of the computer (18), the output of which is connected to a digital-to-analog converter at the output (16) of the conversion block (15). ).