TR2021002832U5 - EXPIRATORY VALVE USED IN RESPIRATORS - Google Patents

Abstract

The invention is an expiratory valve (1) that can be located in an air flow line (I) in a breathing device used to regulate patient breathing. innovation; said expiratory valve (1) to be able to control the breathing exchange between the patient's inspiratory and expiratory cycles; a valve part (10) capable of at least partially limiting the air passing through said air flow line (I) and for detecting the pressure and flow rate of the air advanced in the air flow line (I) at the transition to the expiratory cycle; at least one flow pipe (21) through which air flow is provided in the vicinity of said valve part (10), at least one membrane (25) configured to create a pressure and flow velocity difference in the flow pipe by at least partially slowing down the air flowing in said flow pipe (21) at least one measuring section (20) having at least one first opening (221) and at least one second opening (231) to be used in determining this pressure difference and flow velocity by being positioned on substantially opposite sides of said membrane (25) in the flow pipe (21) ) is included.

Description

DESCRIPTION EXPIRATION VALVE USED IN RESPIRATORS TECHNICAL FIELD The invention is a respiratory system used specifically for the regulation of patient breathing. with an expiratory valve that can be located in an air flow line in the device PRIOR ART breathing or ventilator device; It is one of the medical devices used in hospitals.

It provides the respiratory function, which is a vital function, artificially. These devices by creating gas streams with generally positive pressure according to the preset settings. it allows the lungs to inflate intermittently so that the distorted gas attempts are made to correct the change. Positive generated by ventilator devices external support of respiratory system functions by pressure and respiratory It ensures the elimination of the risk of death that may occur due to deficiencies.

Ventilators can produce artificial breaths with negative or positive pressures. Modern ventilators are computerized microprocessor controlled machines.

Recent epidemics have caused the need for ventilators. has increased. Depending on respiratory diseases, they settle in the lungs of the patient and The virus multiplying here causes the lung membrane to become infected and inflamed. is happening. This inflammation is called pneumonia. This is it severe in the patient's capacity to use his lungs due to inflammation rate is decreasing. This is where the breathing apparatus comes into play. Technical A breathing device called a ventilator delivers oxygen to the patient's lungs. provides reinforcement in sending. In short, the ventilator acts as an artificial lung. undertakes.

The expiratory valve is the most widely used respiratory device to regulate patient breathing. It is one of the essential parts. Controls the level of pressure applied to the patient and It serves to measure the air returning from the patient. Expiratory valves are very sensitive and high It must be in a flow-permeable structure. There are expiration valves to be used. produced so far There are two types of expiratory valves. The first one is single use and has low sensitivity and are high-cost types. The second one is very usable and its costs are very high. is high. Some hospital managements change patients in order to prevent these valves from breaking. It does not even sterilize the valves. From the usage count problem because; hospitals use the expiration valve without sterilizing it. of valves having electronic circuit on it, valves are very fragile against sterilization doing. For this reason, hospitals do not clean these valves in order not to damage them. uses. For this reason, the risk of infection that will be transmitted from patient to patient is very high. raises. In addition, some hospital managements use disposable expiration Due to the high cost of the valves, the flow measuring parts of these valves should not be used. operates the ventilation devices without using it and connects it to the patient. This It is a very dangerous solution since the air coming from the patient is not measured on the way to the solution. method. How efficiently the ventilation device is working or leaks in the connections Since information such as whether there is or not, the patient is putting his life in danger.

In addition, it is very important to have an electronic circuit on the valves that operate with high precision. Even for use, it can cause rapid deterioration during sterilization. is happening.

In addition to these described structures, expiratory valves known in the art treats It cannot work with the desired sensitivity. The flow sensor in the valves low measurement accuracy, patient and ventilation device adversely affect synchronization. The efficiency of the flow sensor does not work, the ventilator needs to understand the patient's need for breath. hinders. For this reason, patient and respiratory device (mechanical ventilator) compatibility deteriorating; patient and ventilator conflict problem occurs.

As a result, all the above-mentioned problems are a novelty in the relevant technical field. does not make it mandatory.

BRIEF DESCRIPTION OF THE INVENTION The present invention is designed to eliminate the above mentioned disadvantages and relates to an expiratory valve to bring new advantages to the field.

It is an object of the invention to measure precision for use in ventilators. to introduce an improved, easier-to-use expiratory valve.

All the above-mentioned purposes that will emerge from the detailed description below. The present invention, in particular, to realize patient breathing in an airflow line in a breathing apparatus used for the regulation of It is a positionable expiratory valve. Accordingly, its novelty is the mentioned expiration. valve to keep breathing between the patient's inspiratory and expiratory cycles. to be able to control; air passing through said air flow line at least a partially restrictive valve section and detecting the pressure and flow rate at the transition to the expiratory cycle to provide; air flow through said valve partial neighborhood The at least one flow pipe provided is the largest of the air flowing in said flow pipe. It will slow down at least partially, creating a pressure and flow velocity difference in the flow pipe. at least one membrane configured in such a way that said membrane in the flow pipe It is essentially positioned on opposite sides of this pressure difference and the flow rate is determined. at least one first opening and at least one second opening for use in contains at least one measurement portion. Thus, measurement in ventilators An expiratory valve structure with improved sensitivity and ease of use is achieved. is being done.

A feature of a possible embodiment of the invention is that the valve part and the measuring part it is configured to be disassembled and attached to each other. Thus, expiration valve can be easily sterilized.

Another possible embodiment of the invention is characterized by the flow tube of the membrane. Membrane with at least one frame and air flow that can be positioned on the at least one membrane capable of at least partially rotating air passage to have a part. Thus, the flow pipe through the membrane frame part A precise measurement possibility with the movement of the membrane while positioning on it is provided.

Another possible embodiment of the invention is characteristic of the first mentioned disclosure. and air to sensors provided on the breathing apparatus of said second opening. is that it can provide the transition. Thus, depending on the air flow in the measurement section, It is ensured that the pressure and flow rate can be determined.

Another possible embodiment of the invention is characterized by air flow in the air flow line. switching between inspiratory and expiratory cycles by limiting its passage There must be at least one cover on the valve part to be able to control and can be actuated by at least one control element of said cover is that. Thus, flow control can be provided in the air flow line.

It is characteristic of another possible embodiment of the invention that said control element is that the cover can be moved pneumatically. Thus, the system Preventing unwanted malfunctions by removing them from electronic parts is provided.

Another possible embodiment of the invention is characterized by the flow tube of the membrane. may be positioned between at least one first piece and at least one second piece on the is that. Thus, in placing the membrane between the first piece and the second piece, ease of assembly is provided.

BRIEF DESCRIPTION OF THE FIGURE In Figure 1, a representative perspective view of the expiratory valve of the invention given.

In Figure 2, a representative exploded view of the expiratory valve of the invention given.

In Figure 3, a representative of the valve part in the expiration valve, which is the subject of the invention, is shown. exploded view.

In Figure 4, a representative of the measuring part in the expiration valve of the invention exploded view.

DETAILED DESCRIPTION OF THE INVENTION In this detailed description, the subject of the invention is only intended for a better understanding of the subject. It is explained with examples that will not have any limiting effect on the subject.

In Figure 1, a representative perspective view of the inventive expiratory valve (1) given. Accordingly, said expiration valve (1) is used in breathing devices. is used. Expiratory valve (1) in ventilators, the discharge from the patient It is located in the part where the air is transferred to the breathing apparatus. expiration valve (1); While giving respiratory support to the patient, it provides breath control and breathes. detecting the air pressure and flow values in the breath during the control it provides. In this way, the patient's health status depending on the breathing characteristics detection is facilitated and treatment can be continued effectively.

Figure 2 is a representative exploded view of the expiratory valve (1) which is the subject of the invention. given. Accordingly, said expiration valve (1) is an air flow line (I). is located on. This air flow line (l) is removed from the patient as mentioned. It is the part where the evacuated air is advanced. Expiratory valve (1) at least one valve section (10) and at least one measuring section (20). Said valve part (10) and said measuring part (20) can be detachably connected to each other.

In this way, ease of use and sterilization can be provided. Valve section (10) so as to at least partially limit the air passage in the air flow line (l). is configured. The mentioned measurement part (20) is the discharge from the patient. It allows to determine the pressure and flow rate of the air.

In Figure 3, the valve part (10) in the expiration valve (1), which is the subject of the invention, A representative exploded view is given. Valve part (10) as mentioned above be able to at least partially slow down and stop the advance of air in the flow line (l) is configured as follows. In this way, the patient's inspiration and expiration It provides mechanical control of the transition between the cycles. as a result of changes in the volume of the inspiratory and expiratory chest cavity occurs with pressure changes in the lung. inspiration; for the lung It is the situation where the pressure is lower than the atmospheric pressure. If expiration on the contrary, the intrapulmonary pressure is higher than the atmospheric pressure. is the status. With the transition cycle between these states, the patient can breathe and can give. In order to provide this, at least one body (11) and at least one cover (13) that can close the air flow line (I) in said body (11) are available. Said body (11) is on the air flow line (l). is located. Said cover (13) is a piece provided on the body (11). it is placed in the cover opening (12). The opening and closing of the cover (13) is at least provided by a control element (14). Said control element (14) preferably configured to open and close the cover (13) pneumatically is an element. By means of the control element (14), the cover (13) is opened and It can be closed, allowing the patient to breathe in and out between the inspiration and expiration cycles. may be forced to give. The cover (13) preferably has a cover body (131), a a first intermediate member (132), a second intermediate member (133) and a closer (134) has. Said closure (134) faces the cover opening (12) of the cover (13). is located on the side. The said cover body (131) is the cover (13). structure to the cover opening (12) on the body (11). it provides. If the said first intermediate element (132) and the second intermediate element (133) It ensures that the closure (134) cuts the air flow under pneumatic pressure.

In order to provide this, the first intermediate element (132) is lower than the second intermediate element (133). It is made of soft material. In this way, at least under air pressure can be partially stretched. The control element (14) and the closure mentioned in the invention 134 is essentially capable of closing and opening with the effect of pneumatic pressure.

However, the invention is not limited to this. Instead, electronic or intelligent systems closure is also possible. The advantage of this structure of the invention is expiratory failure of the valve (1) when sterilizing under high temperature and pressure. It is to have a simplified structure for prevention. In this way, expiration valve (1) is prevented from failing in repeated use, manufacturing costs reduced and easier to use.

In Figure 4”, the measurement part (20) in the expiration valve (1) is the subject of the invention. A representative exploded view is given. Accordingly, the measurement part (20) determination of air pressure and air flow rate with the transition from inspiration to expiration ensures that. To do this, there is at least one on the measuring section (20). There is a flow pipe (21). Said flow pipe (21) is essentially air flow It is positioned on the line (I). The flow pipe 21 is essentially at least one primary part (22) and at least a second part (23). At least on the flow pipe (21) a membrane (25) is positioned. Said membrane (25) preferably the first part It is positioned between (22) and the second part (23). Membrane (25) air flow Configured to at least partially slow down the air passage in the line (l) has been made. Membrane (25) at least one frame (251) and at least one portion of membrane (252) has. Said frame (251) is essentially compatible with the form of the flow pipe (21). It is formed as to be. Said dice (252) is the largest on the frame (251). It is positioned to have at least some freedom of rotation.

The membrane (25) structure is preferably made of stainless steel material. membrane (25) slowing down the passage of air passing through the air flow line (I) due to its structure. allows. In this way, the air pressure in the first part (22) and the second part (23). and there is a difference between flow rates. This difference in air pressure and flow rate It enables the determination of the respiratory characteristics of the patient. Part one (22) and in order to detect the weather data in the second part (23) respectively. there is a first opening (221) and a second opening (231). the first mentioned one fastener (24) on the opening (221) and the second opening (231) are available. Said fasteners (24) include the first opening (221) and the second air values at the opening (231) to a sensor provided in the respirator. (not shown in the figures). Accordingly, two The pressure difference and the flow rate difference between the two can be detected.

In one possible use of the invention; valve with the introduction of air into the patient's lungs (13) control the air flow in the air flow line (I) through the control element (14). is cutting. In this way, the inspiration cycle is provided. inspiration then, when transitioning to the expiratory cycle, the measurement section (20) is the pressure of the air and can detect the flow rate. Membrane (25) with air flow in measuring section (20) vibrates and physical movement of air between the first part (22) and the second part (23). creates a difference between the values. In this way, the pressure and speed are different. is formed. Accordingly, the sensor consists of the first opening (221) and the second opening. (231), patient breath can be controlled depending on the data provided.

With all this structuring; at the expiratory valve (1), they are easily A removable valve portion (10) and a metering portion (20) are provided. Easily It is removable and easy to sterilize and use. is being improved. In addition, via the expiratory valve (1) of the sensor undesirable during sterilization by taking it and carrying it on a respirator. The occurrence of sensor malfunctions is prevented. Expiration valve (1) By simplification, both production costs are reduced and sterilization is achieved. improvement is achieved.

The scope of protection of the invention is stated in the appended claims and it is absolutely detailed explanation cannot be limited to what is told for the purpose of illustration. Because in technique what has been described above by a specialist without departing from the main theme of the invention It is clear that similar structuring can occur in the light of this.

REFERENCE NUMBERS IN THE FOLLOWING 1 Expiratory Valve Valve Part 11 Body 12 Door Opening 13 Covers 131 Cover Body 132 First Intermediate Element 133 Second Intermediate Element 134 Concealer 14 Control Element Measurement Part 21 Flow Pipe 22 Part One 221 First Opening 23 Second Piece 231 Second Opening 24 Connectors membrane 251 Frames 252 Dice (l) Air Flow Line

Claims (1)

CLAIMS The invention is an expiration valve (1) that can be positioned in an air flow line (1) in a breathing device, especially used for regulating patient breathing. so that said expiration valve (1) can control the breath exchange between the patient's inspiration and expiration cycles; a valve part (10) that can at least partially limit the air passing through the said air flow line (I) and to ensure that the pressure and flow rate of the air advanced in the air flow line (I) are determined during the transition to the expiration cycle; At least one flow pipe (21) through which air flow is provided in the neighborhood of the said valve part (10), at least one membrane (25) configured to create a pressure and flow velocity difference in the flow pipe by at least partially slowing down the air flowing in the said flow pipe (21) , At least one measuring section (20) having at least one first opening (221) and at least one second opening (231) to be used in determining this pressure difference and flow velocity by positioning essentially on opposite sides of said membrane (25) in the flow pipe (21) ) is included. It is an expiration valve (1) according to claim 1 and its feature is; valve part (10) and measuring part (20) are configured to be disassembled and attached to each other. It is an expiration valve (1) according to claim 1 and its feature is; It has at least one frame (251) that can enable the membrane (25) to be positioned on the flow pipe (21), and at least one part of the membrane (252) that allows air passage by rotating at least partially relative to the membrane (25) with air flow. It is an expiration valve (1) according to claim 1 and its feature is; said first opening (221) and said second opening (231) are capable of providing air passage to the sensors (not shown in the figures) provided on the breathing apparatus. 5. It is an expiration valve (1) according to claim 1 and its feature is; the presence of at least one cover (13) on the valve part (10) in order to control the passage between the inspiration and expiration cycles by limiting the air passage in the air flow line (I), and that the said cover (13) can be activated by at least one control element (14). 6. It is an expiration valve (1) according to claim 5, and its feature is; said control element (14) can move the cover (13) pneumatically. 7. It is an expiration valve (1) according to claim 1 and its feature is; the membrane (25) is positionable between at least one first piece (22) and at least one second piece (23) on the flow pipe (21).