SU1047477A1 - Autonomous pneumatic perfusion apparatus - Google Patents

Description

The invention relates to medical technology, namely to artificial and auxiliary blood circulation apparatus.

A known apparatus for cardiosynchronization, comprising a pump with a pneumatic camera, a synchronization unit based on electrocardiografiogram (ECG) signals, a computing system — electro-pneumatic and electro-hydraulic converters, amplifiers, power supply units, filtering units for matching elements, as well as pressure and vacuum sources, regulators, manometers and receivers C The disadvantages of the known apparatus of its arrangement are impossible without converters of hydraulic and pneumatic signals into electrical ones and vice versa, - high Sensitivity ECG interference ..

A device for blood pumping is also known, which contains a pneumatic pulse generator (PGI), a blood pump, a heart activity sensor (DDS), and an operating mode selection unit built on the basis of the OR element and two pneumatic relays Cz.

However, during operation of the known device, it is impossible to provide automatic switching of the cardio-synchronized perfusion mode to the perfusion mode from the pulse generator during cardiac arrest and the reverse switching of the operating modes, when the contraction of the heart resumes.

The purpose of the invention is to improve the quality of perfusion by automatically switching the cardiosynchronized perfusion mode to the perfusion mode from a pulse generator during cardiac arrest and reverse, switching modes of operation when heart contractions are resumed.

The goal is achieved by the fact that an autonomous pneumatic perfusion device containing a blood pump, a pneumatic pulse generator, a pressure regulator, a reversible distributor, pressure gauges, a gearbox, a receiver, an oxygenator and a synchronization unit, is equipped with two pneumatic relays, one of the chambers of which is spring-loaded, has three membranes. a pneumatic relay, one of the chambers of which is spring-loaded, with a capacity of a constant volume and an adjustable choke, the input of a spring-loaded chamber of a three-membrane pneumatic relay through p The adjustable throttle is connected to the overpressure line, and the control chamber input is connected to the output of the synchronization unit, the output of the three-membrane pneumatic relay is connected via a constant volume tank to the switching chambers of both pneumatic relays, the inputs of the spring-loaded chamber J of the first pneumatic relay to the overpressure line, the output of the first pneumatic relay is connected to the input of the pneumatic pulse generator 1 inlet of the spring-loaded chamber of the second pneumatic second relay connected to the output of the pneumatic pulse generator and the output synchronization unit and the output of the second pneumatic relay impulsator connected via a control input of a reversing valve.

The drawing shows a diagram of an autonomous pneumatic perfusion device.

The device consists of a pneumatic pulse generator 1, a switching unit 2, a delay unit 3, a pulser 4, a synchronization unit 5, a reversing distributor 6 of a pressure regulator 7, a pressure gauge 8, a receiver 9, an oxygenator 10, a compressed gas cylinder 11, a gear 12, a pressure gauge 13 , pneumotumboiler 14, pump 15, catheter 16 from the ventricle 17 of the patient's heart.

The pneumatic generator and the motors 1 consists of a relay 18, an adjustable throttle 19, a tank 20 connected between the output of the relay 18 and its control camera. The switching unit 2 consists of two relays 21 and 22., The control chambers of which are connected to the pneumo-tumbler 14, and the switching chambers - with the output of the delay unit 3. The delay unit 3 consists of a relay 23, a tank 24 and an adjustable throttle 25 connected between the nozzle of the relay 23 and the pneumotransmitter 14. The pulsator 4 consists of two relays 26 and 27 and an adjustable throttle 28 connected between the relay output 26 and the relay control camera 27.

The device in the perfusion mode of the pulse generator works as follows.

The pneumatic switch 14 is set to manual control, the delay unit 3 and the synchronization unit 5 are turned off, and the switch 2 switches the power to the pneumatic pulse generator 1 and connects its output to the pulse 4. The system supply pressure is set by the gearbox 12 and. controlled by the pressure gauge 13. The pressure reducer 7 is adjusted by the pressure gauge 8 by setting the pressure in the receiver 9 at the inlet to the reversing distributor b.

The switching frequency of the reversing distributor b is set on the pneumatic generator and pulses by adjusting the throttles 19. When gas is generated from the pneumatic pulse generator 1 through the relay 22 in the relay 26, its spring is pressed and the gas from the gearbox 12 passes through the camera 26 and the camera 27 of the relay 27 to the control valve of the reversible distributor b and through an adjustable throttle 28 into the chamber of the relay 27. Reversible valve 6 is activated and switches the pneumatic chamber of the pump 15 to the receiver 9, the pump 15 starts systole. After filling Neither the chamber of the relay 27 is activated, and the gas supply to the reversing distributor b is stopped, and the pneumatic drive chamber of the pump 15 switches from c to the atmosphere, the pump starts to be filled with blood from the oxygenator 10 of the power supply line of the throttles 19 and 28 is divided by the relay 26, which eliminates their mutual influence when adjusting systole duration and frequency. The device in the period of renewal of the contraction of the heart works as follows. The catheter 16 from the ventricle of the heart 17 is connected to the synchronization unit 5, the pneumatic switch 14 is switched to the Automatic position, while the gas from the gearbox 12 passes to the synchronization unit 5 to the delay unit 3 and to the relay chambers 21 and 22, the switching unit 2, and the relay 21 turns off the power of the pneumatic pulse generator 1, and the relay 22 switches the camera of the relay 26 to the output of the synchronization unit 5. The signal from the synchronization unit 5 appears during the diastole of the heart 17 and into the camera of the relay 23 of the delay 3 and the sequence of the relay 22 to the relay kagler 26 that works by skipping From the gearbox 12 through the normally open relay 27 to the reversing valve 6, which connects the receiver 9 to the pump 15, blood is released during the diastole of the heart until the chamber 27 is filled with gas through the choke 28 and it does not switch reversible distributor 6 to the atmosphere. Thus, the adjustment of the throttles 28 determines the systole time of the pump 15. The delay unit 3 works as follows. Gas through an adjustable choke 25 and a normally open relay 23 e-apolnet capacitance 24, which is connected to the cameras of the relay 21 and 22; The gas from the synchronization unit 5 is fed to the KC1mer of the relay 23, which is triggered, and the capacitance 24 through the chamber of the relay 23 is discharged into the atmosphere. If the signal from sync unit 5 disappears; when the G7 heart stops, the relay 23 remains normally open, the capacitance 24 is charged through the adjustable throttle 25, and after the relays 21 and 2.2 are filled, they switch. Relay 21 passes gas to pneumatic pulse generator 1, and relay 22 connects pneumatic pulse generator 1 to chamber 26 of pulse 4. The pump is controlled by a signal from pneumatic pulse generator 1. At the first signal from the heart 17, the synchronization unit 5 is activated and the relay 23 Switch. Tank 24 to the atmosphere. The switching unit 2 is activated, turns off the pneumatic pulse generator 1 and connects the synchronization unit 5 to the pulser 4. The device starts to work on the signal. The presence in the device of a delay unit provides an adjustable delay and eliminates the effect of the forced donor pump on the heart 17 by pump 15, which allows the heart to be relieved as much as possible and ensures a constant perfusion of the body even when the heart is working with frequent stops. The presence of the switching unit allows automatic switching off and switching on of the pneumatic generation of pulses 1 into operation and switching the impulse from the pneumatic pulse generator 1 to the synchronization unit 5, eliminating their mutual influence, which ensures a clear and reliable operation of the device with a constant perfusion of the body reduces gas consumption. The presence of an additional turnip in the pulsator allows an adjustable throttle - frequency adjuster to isolate the line, which greatly improves the accuracy of the siotola duration and the reliability of the device, by eliminating the possibility of mutual influence of the frequency and systole duration adjustment. Autonomous power supply of the device from the compressed gas cylinder, simplicity of design, small overall dimensions and weight of the device, as well as the use of a synchronous pneumatic unit in the device. By changing the pressure in the ventricle of the heart, -. Exceptional anti-noise immunity allows synchronized perfusion during patient transport and under the conditions of care, while ensuring automatic switching of operating modes.

Output

Claims (1)

ί 54) (57) A stand-alone PNEUMATIC perfusion device containing a blood pump, a pneumatic pulse generator, a pressure regulator, a reversible distributor, pressure gauges, a reducer, a receiver, an oxygenator and a synchronization unit, characterized in that, in order to improve the quality of perfusion by automatically switching the mode cardiosynchronized perfusion to the perfusion mode from the pulse generator during cardiac arrest and the reverse switching of modes when resuming heart contractions, the device is equipped with two air by mathematical relays, one of the chambers of which is spring-loaded, a three-membrane pneumatic relay, one of the chambers of which is spring-loaded, with a constant volume capacity and adjustable throttle, the input of the spring-loaded chamber of the three-membrane pneumatic relay is connected to the overpressure line through an adjustable throttle, and the control camera input - to the 'output of the synchronization unit, the output of the three-membrane pneumatic relay through a constant volume tank is connected to the switching chambers of both pneumatic relays, the inputs of the control chambers to which and the input of the spring-loaded chamber of the first pneumatic relay are connected to the overpressure line, the output of the first pneumatic relay is connected to the input of the pneumatic pulse generator; the input of the spring chamber of the second pneumatic relay is connected to the output of the pneumatic pulse generator and the output of the synchronization unit, and the output the second pneumatic I relay is connected via a pulser (to the control input of the reversible one). distributor. B