RU89358U1 - DEVICE FOR DETERMINING ENERGY EXCHANGE OF THE PATIENT - Google Patents

Abstract

A device for determining the energy exchange of a patient, including a monitor with a capnometry channel module, an artificial lung ventilation apparatus, an endotracheal tube, inhalation and expiration lines and an oxygen gas analyzer, characterized in that it includes an additional oxygen gas analyzer and an air mixture sampling and transmission line, one end of which is connected via an adapter to the endotracheal tube, and the other end is connected to a moisture separator connected to the capnometry channel module, while one oxygen analyzer is installed detecting input to the inspiratory line, and the second analyzer the air - at the output of the exhalation line, and is irreversible inspiratory valve outlet pipe.

Description

The utility model relates to medical equipment and can be used in anesthesiology, intensive care and intensive care to monitor the patient's condition during mechanical ventilation. The utility model allows to measure the concentration of carbon dioxide and oxygen in the air mixture inhaled and exhaled by the patient.

A device for determining the energy exchange of a patient (Metabolic MONITORING LITERATURE ROCKET - AA 2191 - 00 (3/95).

It consists of an artificial lung ventilation unit and a stationary metabolograph. The metabolograph is equipped with a monitor with a capnometry channel module, oxygen and carbon dioxide gas analyzers with pressure converters, a gas calibrator and a pump for discharging the air mixture. The known device also contains a line of inspiration and expiration connected to the endotracheal tube. An artificial lung ventilation unit is connected to the inspiratory and expiratory line and, through an additional line, to gas analyzers of oxygen and carbon dioxide of the metabolograph.

The disadvantages of the known device are the design complexity and the impossibility of moving it without dismantling and using special means of transportation, as well as the inability to measure the current energy exchange of the patient.

The objective of the utility model is to eliminate these drawbacks.

The technical result of the utility model is to simplify the design of the device, eliminating the use of vehicles to move the device, and also providing the ability to measure the current energy exchange of the patient.

The technical result is achieved by the fact that the device for determining the patient’s energy exchange, including a monitor with a capnometry module, an artificial lung ventilation apparatus, an endotracheal tube, inhalation and expiration lines, an oxygen gas analyzer, contains an additional oxygen gas analyzer and an air mixture sampling and transmission line connected at one end through an adapter to the endotracheal tube, and the other end connected to a dehumidifier connected to the capnometry channel module. In this case, one oxygen analyzer is installed at the inlet of the inspiratory line, and the second gas analyzer is installed at the outlet of the exhalation line.

The utility model is illustrated by the device diagram.

A device for determining the energy exchange of a patient consists of a monitor 1 with a module of the channel of capnometry 2, a line for the selection and transmission of the air mixture 3, an endotracheal tube 4 connected by a tee 5 to the inspiration and expiration lines. The inspiration line includes sequentially located mechanical ventilation apparatus 6 and a corrugated hose 7, which is connected to the endotracheal tube 4 through a tee 5. At the outlet of the corrugated hose 7, a non-reversing valve 8 is built-in. Moreover, the mechanical ventilation apparatus 6 and corrugated hose 7 are connected through a T-shaped the connector 9 is connected to an oxygen sensor 10 connected to an oxygen gas analyzer 11. The exhalation line consists of a corrugated hose 12, one end of which is connected to a tee 5, and the second to The net is connected to the atmosphere through a ventometer 13. At the outlet of the corrugated hose 12, a T-shaped connector 14 is installed in front of the ventometer 13, connecting the oxygen sensor 15 to the oxygen gas analyzer 16. An adapter 17 is installed on the endotracheal tube 4, which is connected to the sampling and transmission line of the air mixture 3 , which is a thin silicone tube connected through a dehumidifier 18 to the module of the channel capnometry 2.

A device for determining the energy exchange of a patient works as follows.

When you inhale the air mixture from the artificial lung ventilation apparatus 6 through the connector 9 enters the oxygen sensor 10 and the gas analyzer 11, which registers the oxygen content in the air mixture. Next, the air mixture through the corrugated hose 7 and the non-reversing valve 8 is fed into the endotracheal tube 4 and the patient's lungs. At the same time, the line of sampling and transferring the sample of the air mixture 3 from the endotracheal tube 4 through the adapter 17 breathes the air mixture through the moisture separator 18 into the capnometry channel 2, after which the monitor 1 gives the value of the carbon dioxide content in the inspiration line. When exhaling, the non-reversible valve 8 closes the inspiratory line, and air from the patient’s lungs through the endotracheal tube 4 is directed through the ventilator 13 into the atmosphere. In this case, the ventilometer 13 gives indications of the minute volume of the lungs, and the oxygen analyzer 15 - the oxygen content in the air exhaled by the patient. At the same time, the line for sampling and transferring the sample of the air mixture 3 from the endotracheal tube 4 is exhaled by the patient’s lungs through a dehumidifier 18 to the capnometry channel 2, and monitor 1 displays the value of the carbon dioxide content in the patient exhaled air.

Thus, when using the proposed device, you can constantly monitor the energy exchange of the patient.

Claims (1)

A device for determining the energy exchange of a patient, including a monitor with a capnometry channel module, an artificial lung ventilation apparatus, an endotracheal tube, inhalation and expiration lines and an oxygen gas analyzer, characterized in that it includes an additional oxygen gas analyzer and an air mixture sampling and transmission line, one end of which is connected via an adapter to the endotracheal tube, and the other end is connected to a moisture separator connected to the capnometry channel module, while one oxygen analyzer is installed detecting input to the inspiratory line, and the second analyzer the air - at the output of the exhalation line, and is irreversible inspiratory valve outlet pipe.