HU188587B - Arrangement for supplying and metering the oxygen lessening in breathing test set of closed circulation system - Google Patents

Abstract

The present invention relates to a method for replacing and quantifying oxygen consumed by a closed circulatory respirator, and to controlling measurements performed on devices that are loaded on the basis of instantaneous oxygen consumption, which may be used in medical practice and other fields, such as pulmonary function tests, metabolism and other internal medical examinations, fitness and stamina. patients, athletes, or rehabilitated patients. The arrangement according to the invention comprises a closed circulation circuit from a measuring bell (2), a fan (3), an absorbent (4) and an air cooler (5), and a connected signaling and control unit (15) and a chronometer (7) connected thereto. 2) and an air cooler (5) with a flapper. The novelty of the invention is that an oxygen bottle (8) is connected between the fan (3) and the absorber (4) via a solenoid valve (13), wherein the oxygen bottle (8) is known as a reductor (or) in a high pressure chamber (10). ), low pressure pressure regulator (11) or connected to the solenoid valve (13) via a low pressure chamber (12), the control input of which is connected to the output of the control unit (15) via a power stage (16); that the helium analyzer (30) is connected in parallel with the absorber (4), the output of which together with the outputs of the control unit (15) and the signal generating (14) is a data processing unit. preferably, the microcomputer (17) is connected to an input, the output device (28) of which is connected to its output. (Figure 1) -1-

Description

FIELD OF THE INVENTION The present invention relates to an arrangement for replacing and measuring the amount of oxygen consumed by a closed-circuit respiratory tester and controlling measurements on instantaneous oxygen demand training devices that can be used in medical practice and other applications such as lung function tests, metabolism and other and endurance tests in patients, athletes, or rehabilitated patients.

There are two types of respiratory equipment known: 10 rabbits and a closed circulation system.

The advantage of open system devices is that the patient receives air from a gas space of a quality and condition appropriate to his / her usual environment. However, they have the disadvantage that the measurement and calculation of oxygen consumption is only possible indirectly, which makes the equipment expensive and inaccurate. Such an open system device is known e.g. No. 4,078,554. U.S. Pat.

Closed-circuit respiratory examinations can also be of two types, one or two-ring. The single-pass breathing apparatus includes a bell, a constant air circulation fan, a carbon dioxide absorber in the exhaled air, and a closed air cooling system that maintains the air at a constant temperature, whereby pen writes on a kynographic unit. The disadvantage of these devices is that, due to the lack of proper oxygen refill, only measurements lasting 1 to 2 minutes are suitable; not for load measurement.

For oxygen refill, MaJomski: Practical Spiroergometry c. Manual Medicine Needle Valve (Medicina, Budapest, 1979, pp. 49-51) uses a calibrated ratometer to measure oxygen consumption. The disadvantage of this solution is that the 21% O ₂ stabilization required for the respiratory function test is lengthy and cumbersome. In addition, it is not suitable for the so-called helium dilution principle. residual volume. 40

- In dual-breath breathing apparatus, the oxygen consumed is supplied from a second bell, where consumption is measured by reducing the volume of oxygen in the second bell (pressure constant).

The disadvantage of this arrangement is that the operator operating the apparatus requires constant intervention during the measurement, since the second oxygen-containing bell is often refilled in a high oxygen demand load test, which is from a high pressure 50 bottle containing 100% oxygen. It happens. A further disadvantage is that the second bell for oxygen refill has to be provided with a second fan circuit, which is equivalent to the circulation bell of the first bell, which is complicated and expensive. 55

Examples of single-ring devices described above are Expirograph 1600 from Gould-Godart, Pulmonet III from the US, Volutest VT-3 from Mijnhardt from the Netherlands, VO-11 from Medicor, two-ring devices from the Gould-Godart Pulmotest, Medicor θθ PT- 400, respectively. PT-400 L models.

Constantly the same amount of material, e.g. A solution for gas transmission and measurement is known from U.S. Patent No. 173,021, which, however, is unsuitable for respiratory function tests, due to low power (90 l / h) and achievable accuracy. '

No. 555,674. U.S. Patent No. 4,198,198; System Respirator (breathing apparatus) combined with spirometers. The advantage of the device is that the amount of air moved per minute by the patient per breath can be determined with great precision even during forced breathing. However, it has the disadvantage that it is not suitable for measuring oxygen consumption.

Csordás: Pneumatic Control Engineering (Technical Publisher, Bp. 1966) c. For example, his book describes how to dispense a constant pressure gas from a high pressure gas cylinder.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above drawbacks by providing an arrangement which combines the advantages of the known solutions.

The present invention is based on the discovery that, when a constant pressure oxygen is generated in a suitably sized low pressure chamber, it is fed through a continuously operated solenoid valve to a closed circulation system with a patient connector and controlled by a steady-state respiratory mean value. then the oxygen consumption is proportional to the solenoid opening hours.

Based on the foregoing recognition, the object has been achieved by providing an arrangement wherein the closed circulation air gun comprises a measuring bell, a fan, an absorber and an air cooler to which a signaling and control unit is connected and a chimograph is connected between the bell and the air cooler.

The novelty of the invention is that an oxygen cylinder is connected between the fan and the absorber via a solenoid valve, wherein the oxygen cylinder is known per se on a reducer, high pressure chamber, low pressure regulator or valve. connected via a low pressure chamber to the solenoid valve, the control input of which is connected via a power stage to the control unit output; that helium gas analyzer is connected in parallel to the absorber, the output of which is coupled to the input of a data processing unit, preferably a microcomputer, to which a load device is connected, with the outputs of the control unit and the signal generator.

An arrangement for replacing and measuring oxygen consumption from a closed-circuit respirator according to the present invention will now be described in more detail with reference to the accompanying drawing, in which Figure 1 is a block diagram of the arrangement comprising:

a closed circulation circuit 1 consisting of a measuring bell, an air supply fan 3, an absorber 4 and an air cooler 5 to which a patient connector 6 is connected between the measuring bell 2 and the air cooler 5, and a chimograph 7 and a symbol 14 are connected to the measuring bell. A control unit 15 is connected to the output of the signal generator 14, which is connected via a power stage 16 to the control input 13 of the solenoid valve. The outlet of the solenoid valve 13 is connected between the fan 3 and the absorber 4 in the closed circulation circuit 1 and inlets 12 in a low-pressure chamber, 11 in a low-pressure regulator, 10 in a high-pressure

It is connected to 8 8 oxygen cylinders through 188 587 chambers and 9 reducers. In the figure, it is further noted that helium gas analyzer 30 is connected in parallel with absorber 4 and the outputs of control unit 15, signal generator 14 and helium gas analyzer 30 are connected to inputs 5 of microcomputer. The microcomputer 17 includes peripheral interfaces 23, 24, a programmable real-time clock 22, an analog-to-digital converter 21, a bus system 18, a central processing unit 19 and a memory 20, wherein the bus system 18 is connected to all other units. connected to a peripheral interface 25 keyboards and display units, a cathode ray tube display unit 26 and a thermal printer 27, programmable realtime 22 with control unit 15, analog / digital converter 21 with signal generator 14 and helium gas analyzer 30, second peripheral interface 15 24 It is connected to a device 28 and a modular data logger 29, and a loading device 28 is connected to the interface output of the second peripheral 24.

The arrangement according to the invention operates as follows:

The measuring bell 2 is a counterbalanced, water-tight measuring bell, the balance of which is provided by the air supply fan 3. The fan 3 maintains a constant air circulation 25 and prevents the exhaled air from being re-breathed, and its speed and air flow are controlled by a submersible motor. The CO 3 vapor produced during breathing is absorbed by the absorber 4 and the air cooler 5 prevents the circulation of the circulating air from heating up. 39 Changes in volume measured with a measuring bell 2 are recorded on the chymograph 7 by a pen that is mechanically connected to it.

Depending on the resting and dynamic sensitivities and the degree of oxygen consumption, the refill of oxygen from the 8 cylinders is reduced by 9. the high pressure chamber 10, the low pressure pressure regulator II and the sufficiently large volume low pressure chamber 11 make it possible.

The pressure of the oxygen cylinder 8 may vary from 200 to 1500 kPa, which is reduced by the reducer 9 to a pressure of 100 kPa ± 20 kPa, which is maintained within the same range (100 kPa ± 20 kPa) of the high pressure chamber.

The outlet of the high pressure chamber 10 is connected to the inlet of the low pressure pressure regulator 11, which has an air flow capacity of, for example, 4001 / h and an outlet pressure of 2.5 kPa.

Connected thereto is a low-pressure chamber 12 having a volume of 4000 cm ³ , and at its outlet, independently of the pressure of the oxygen cylinder 8, a very accurate pressure value 59 can be set in the range of 500-5000 Pa. The outlet of the low pressure chamber 12 is connected to the pneumatic inlet of the solenoid valve 13 and its pneumatic outlet to the pneumatic tube system of the closed circulation system 1 so as to provide a constant pneumatic resistance due to the fixed geometry of the connecting pneumatic conduit.

The signal generator 14, as shown, is connected to the measuring bell with two inputs: the first input is provided with a volumetric transducer potentiometer 60 which provides a signal proportional to the displacement of the bell 2, i.e., a second input with a temperature sensor. which at its output provides a signal proportional to the temperature of the air in the closed circulation channel 1 in the form of an analog electrical signal 65. The control unit 15 provides pulses of a duration proportional to the amount of oxygen consumed to the input of the power stage 16, which transmits this signal to the control input of the solenoid valve 13 and ensures that the solenoid valve 13 opens at appropriate intervals. close.

A stabilized voltage adjustable at the second output of power stage 16 is generated by means of a potentiometer, thereby providing the required stabilized airflow power (about 1001 / min) for the tests with 3 fans in the closed circuit 1.

The second output of the control unit 15 is connected to the programmable real-time clock 22 of the microcomputer 17, so that the same pulses as the control pulses of the solenoid valve 13 are input, from which the microcomputer 17 calculates the oxygen consumption.

The person operating the apparatus of the present invention operates the system via the thermoplate and display unit 25, the cathode ray tube display unit 26 including typing patient data, selecting a measurement mode, displaying and printing the calculated data at the end of the measurements.

The loading device 28 connected to the second peripheral interface 24 of the microcomputer 17 may be, for example, a bicycle ergometer or a conveyor belt ergometer for loading the patient in a well-defined manner over a wide range. The modular data acquisition device 29 stores the generated respiratory function parameters according to the patient identification data.

The volume change at the first input of the analog-to-digital converter 21 calculates the parameters of the lung function tests stored in the memory 20 of the microcomputer 17, corrects the previous jc using temperature signals at the second input, and calculates the patient's normal parameters and their percentages. . There are several parameters of respiratory function that are proportional to oxygen consumption.

The third input of the analog-to-digital converter 21 is connected to the gas analyzer output of helium 4 so that residual volume measurements can also be made.

In accordance with the intermittent opening times of the solenoid valve 13, the instantaneous oxygen consumption measurement can be calculated in real-time for a short-term (20-40 sec) gradually sliding test period with the microcomputer 17. and, to the exercise equipment 28, provide a workout program that maintains an optimal increase in oxygen consumption per kilogram of body weight per minute, thereby ensuring that the patient is not under- or overloaded, but in an optimum manner. maximum load.

Claims (2)

Patent claims An arrangement for supplying and measuring a quantity of oxygen consumed by a closed-circuit breathing apparatus comprising a closed circulation circuit consisting of a measuring bell, a fan, an absorber and an air cooler, and a connected signaling and control unit, and a chimograph, characterized in that an oxygen cylinder (8) is connected between the fan (3) and the absorber (4) via a solenoid valve (13), wherein the oxygen cylinder (8) alone 188,587, wherein the microcomputer (7) includes peripheral adapters (23, 24), programmable real-time clock (22), analog-to-digital converter (21), bus system (18), central processing unit (19), and memory (20), wherein the bus5 system (18) is connected to all other units, tz first 23 peripheral interfaces are connected to a keyboard and display unit (25), a cathode ray tube (26) display unit and a thermal printer (27), a programmable real-time clock (22). a control unit (15), an analog-to-digital converter (21) with a signal generator (14) and a helium gas analyzer (30), a second peripheral interface (24) ΐ load device (28) and a modular data logger. (29) is connected. in a known manner on a reducer (9), a high-pressure chamber (10), a low-pressure pressure regulator (11), respectively. connected via a low pressure chamber (12) to the solenoid valve (13), the control input of which is connected via an output stage (16) to the output of the control unit (15); the helium gas analyzer (30) being connected in parallel with the outputs of the control unit (15) and the signal generator (14) to the inputs of a data processing unit, preferably a microcomputer (17), the output of which is loaded by a device (28). is connected. Arrangement according to Claim 1, illustrated therein