KR102204642B1 - Device for preventing the healthcare provider infection during artificial respiration - Google Patents

Abstract

The apparatus for preventing the transmission of artificial respiration infection according to the present invention comprises: a respiratory connector 10 mounted on the face of the patient to perform artificial respiration; Bag 20 connected to one side of the branch pipe 12 configured to communicate with the respiratory connector 10; And a filter module 100 connected to the other side of the branch pipe 12, wherein the filter module 100 includes a connection port 110 directly coupled to the other side of the branch pipe 12, and the connection port 110 ) Through a corrugated pipe 120 connected to the branch pipe 12, a coil tube 130 disposed in the corrugated pipe 120, and a cover 150 coupled to the outside of the corrugated pipe 120 .

Description

Device for preventing the healthcare provider infection during artificial respiration}

According to the present invention, a coil-shaped tube filter and a pleated bag into which the tube filter is inserted are mounted on a bag mask or a bag for artificial respiration after tracheal intubation, so that bacteria and viruses in the patient's saliva, blood, sputum and exhaled air It relates to a technology for removing various causes of infection transmission through a structure that filters and removes.

In fire-fighting emergency situations as well as performing artificial respiration, such as tracheal intubation or bag-mask positive pressure ventilation, medical personnel are likely to be exposed to air, droplets or contact infections.

In particular, during artificial respiration, not only the patient's oral cavity, lung organs, alveoli, but sometimes patient's secretions from the esophagus, stomach, etc., sputum, blood from hemoptysis or hematopoiesis, blood from lacerations such as the patient's orbital cavity, bacteria, There is a very high possibility that the virus and the like will be transmitted directly to medical staff who treat patients.

During artificial respiration, the medical staff performs oxygenation and positive pressure ventilation through the patient's oral cavity, airways, and bronchi at a very close distance to the patient, and performs treatment.The patient undergoing artificial respiration is an emergency critical patient and is based on a team of medical staff. Through treatment, it is carried out in a closed space such as a resuscitation room or an ambulance. In the above treatment process, there is a high risk of exposure to a high concentration of infection vectors and infection by many medical staff.

In addition, since medical staff or medical personnel are in charge of treatment of other patients and guardians, they can serve as the second medium for transmission of infection, so it is very important to manage infections in medical staff and medical environments.

The transmission route of infection can be air, droplet, contact and blood transmission depending on the type of bacteria and virus, and air transmission by breathing, air in the lungs of the patient, droplets and contact transmission by the patient's sputum or saliva , It is possible to propagate by blood from wounds such as hemoptysis of the patient or oral mucosa.

Representatively, tuberculosis and hepatitis HBV (Hepatitis B virus) have a high prevalence in Korea among OECD countries, and antibiotic-resistant bacterial pneumonia such as influenza virus and bacterial pneumococcal is also steadily increasing. In particular, HIV (human immunodeficiency virus) infection, which has a high fatal rate, and severe acute respiratory syndrome virus may threaten not only the safety of medical personnel, but also the safety and life of patients and guardians.

When the patient exhales through oxygenation and ventilation due to the supply of oxygen, which is artificial respiration to the patient, and the positive pressure generated during ventilation, the air inside the lungs is expelled to the outside.In this process, air, droplets, blood, saliva, etc. in the patient's lungs Without filtration, the surrounding medical staff are exposed to and invaded the oral cavity, lungs, and eye conjunctiva of the medical staff directly to the high-concentration infection.

Therefore, after performing a bag mask or tracheal intubation during artificial respiration, medical personnel through secretions such as air, droplets, sputum, and blood discharged from the patient's oral cavity, lungs, and esophagus during ventilation using positive pressure, medical personnel and ambulances, hospitals Exposure and transmission of infections to internal medical spaces, etc., can cause exponential infections to medical workers and medical personnel, patients and guardians who use hospitals, etc. Therefore, measures to prevent the spread of infections through special care and prevention are necessary. .

(Patent Document 1) KR10-1670320 No. B

The present invention is to solve the above conventional problems, by first filtering and removing the air inside the lungs of the patient, droplets, sputum, saliva, bacteria and viruses in the blood through a coil-shaped tube filter to prevent the spread of infection, and In a state where saliva, blood, secretions, etc. are collected in a closed space in the wrinkle bag, it is possible to attach and attach to existing products after use by the patient, while secretions such as internal bacteria, viruses, saliva, and blood can be treated separately. Its purpose is to prevent contamination of the medical field.

In the present invention, after performing a bag mask or tracheal intubation during artificial respiration, a respirator filter having a corrugated pipe and a coil tube inside the corrugated pipe is installed in the respiratory ventilation equipment to remove viruses and bacteria in the lung air during exhalation and positive pressure of the patient, It is to remove various causes of infection transmission to medical personnel and medical sites through a structure that collects secretions such as sputum and blood.It is possible to prevent the spread of infection through exhaled air and secretions of the patient by installing filters such as villi in the shape of a coil tube. Purpose.

In order to solve the above problems, the apparatus for preventing the transmission of artificial respiration infection according to the present invention includes a respirator connector 10 mounted on the face of a patient to perform artificial respiration; Bag 20 connected to one side of the branch pipe 12 configured to communicate with the respiratory connector 10; And a filter module 100 connected to the other side of the branch pipe 12, wherein the filter module 100 includes a connection port 110 directly coupled to the other side of the branch pipe 12, and the connection port 110 ) Through a corrugated pipe 120 connected to the branch pipe 12, a coil tube 130 disposed in the corrugated pipe 120, and a cover 150 coupled to the outside of the corrugated pipe 120 .

The filter module 100 further includes a ring-type filter connected to the coil tube 130.

The corrugated pipe 120 is a translucent material.

The coil tube 130 has a structure in which villi are embedded along the inner surface thereof.

In the present invention, in the case of performing artificial respiration using a mask or tracheal intubation tube mounted on a respiratory ventilation device after ventilation or tracheal intubation with a bag mask, exhaled air that can be discharged through the mask and bacteria, viruses, Prevent the spread of infection to medical staff, medical personnel, and medical environment through special precautions and prevention for exposure to bloodborne infectious agents and the occurrence of infection.

The present invention is to remove various causes of infection transmission through a structure that removes the patient's saliva and virus by mounting a filter for a respiratory ventilation device having a corrugated tube and a coil tube on a mask, and by installing villi in a coil tube shape, exhaling air, It enables the prevention of transmission of infection through secretions such as saliva, droplets, and blood.

1 shows a combination of an artificial respiration infection transmission prevention apparatus having a corrugated tube 120 and a coil tube 130 according to an embodiment of the present invention.
FIG. 2 is an exploded view of the apparatus for preventing transmission of artificial respiration infection of FIG. 1.
3 is a diagram showing a combination of an artificial respiration infection transmission prevention apparatus having a pleated tube 120 and a HEPA filter according to another embodiment of the present invention.
4 shows the operation of the corrugated pipe 120 constituting the device for preventing the transmission of artificial respiration infection.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms. It is provided to be fully informed. Like reference numerals in the drawings refer to the same elements.

1 shows a combination of an artificial respiration infection transmission prevention apparatus having a corrugated tube and a coil tube according to an embodiment of the present invention. FIG. 2 is an exploded view of the apparatus for preventing transmission of artificial respiration infection of FIG. 1.

1 and 2, the apparatus for preventing transmission of artificial respiration infection according to the present invention comprises: a respiratory connector 10 mounted on the face of a patient to perform artificial respiration as a whole; Bag 20 connected to one side of the branch pipe 12 configured to communicate with the respiratory connector 10; And a filter module 100 connected to the other side of the branch pipe 12.

The respiratory connector 10 may be in the form of a mask or an intubation tube.

The bag 20 is connected on the branch pipe 12, which is an air connection pipe constituting the respirator connector 10, to start artificial respiration through positive pressure ventilation and oxygenation. Of course, if available, it may be connected to other oxygen supply means such as an artificial respirator instead of the bag 20.

The bag 20 is a patient valve that functions to deliver breathing gas (oxygen/carbon dioxide) according to inhalation and exhalation while connected to the respirator connector 10, and to discharge breath. When pressing the breathing bag or the breathing bag, use an oxygen storage bag to block exhalation gas from entering, and when placing the breathing bag, an intake valve that provides oxygen gas from the oxygen storage bag to the breathing bag, and oxygen supply when supplementary oxygen is used. It has an oxygen supply tube connector that supplies oxygen through a tube, and an oxygen storage bag that is connected to the breathing bag when supplementary oxygen is used, and is a space where oxygen is temporarily stored.

On the other hand, as another embodiment, the bag 20 may have a structure including the respirator connector 10 integrally.

The filter module 100 includes a connector 110 directly coupled to the other side of the branch pipe 12, a pleated pipe 120 connected to the branch pipe 12 through the connector 110, and the pleated pipe 120 ) Disposed in the coil tube 130, a filter 140 coupled to the outside of the coil tube 130, and a cover 150 coupled to the outside of the corrugated pipe 120.

Referring to FIG. 4, the corrugated pipe 120 has a corrugated portion having a shape that can be stretched to the left and right as having a flexible material and an outer portion extending a predetermined distance while maintaining a uniform diameter from both ends of the corrugated portion. The corrugated portion has a plurality of peaks having a first diameter in a state of being made of a translucent material, and a plurality of valleys connected and arranged to have a second diameter smaller than a first diameter on both sides of the plurality of peaks. That is, a plurality of peaks and valleys are alternately arranged in succession between the pair of outer portions. As an example, the pair of outer portions may have a configuration in which a valley portion and an upper portion are continuously arranged in a state connected to the mountain portion, respectively. In the present invention, the difference between the maximum expanded state and the reduced state of the corrugated pipe 120 is configured to reach 2 times.

The coil tube 130 is placed in a free end type on the inside of the corrugated pipe 120 while the outside of the coil tube 130 is coupled to the filter 140. That is, the inside of the coil tube 130 is in a state in which the flowing material in the corrugated tube 120 can be freely introduced. In the process of using the artificial respiration infection propagation prevention device, the substances introduced into the corrugated pipe 120 sink into the corrugated pipe 120 during the flow of the corrugated pipe 120 or the spiral flow path through the coil tube 130 Flows along. Materials passing through the coil tube 130 are filtered through a filter 140.

In the coil tube 130, villi are formed along the inner surface thereof. The villi function to filter contaminants such as blood and saliva, which are impurities, among substances introduced into the coil tube 130 within the corrugated pipe 120.

In the present invention, a high efficiency particulate air (HEPA) filter is employed as a filter, and the HEPA filter is a kind of air filter. Filters meeting HEPA standards are used in a number of applications, including clean rooms for IC manufacturing, medical facilities, automobiles, aircraft, and homes. These filters must meet certain efficiency standards by the US Department of Energy (DOE). To meet industry standard HEPA standards, air filters must remove 99.97% of particles (via air) larger than 0.3 μm. The ASME industry standards have not been published by governments, but are recognized as authoritative standards by many governments.

The HEPA filter is capable of collecting more than 99.97% of particulate matter with a particle diameter of 0.3㎛.

On the other hand, the HEPA filter may have a tube shape having a donut shape fitted on the coil tube 130, and a coil tube in a state in which a separate fuse 142 is disposed on the inner surface of the HEPA filter 140'. The pollutants discharged through the outlet of (130) are first filtered before being directly filtered from the HEPA filter.

3 is a diagram showing a combination of an artificial respiration infection transmission prevention apparatus having a pleated pipe 120 and a HEPA filter 140 ′ according to another embodiment of the present invention.

Referring to FIG. 3, in a state in which a separate coil tube 130 is not disposed on the corrugated tube 120, the HEPA filter is directly coupled to the outside of the corrugated tube 120.

The present invention is a device capable of preventing secondary infection of medical personnel and medical personnel, patients, and guardians by using the filter module 100 that functions as an infection prevention filter on the bag 20, and the infection of the existing Ambubag As a form of improved vulnerability, it can be provided at low cost in a state where there is no practical respiratory ventilation device that prevents the spread of infection between medical staff and the medical environment.

The present invention is equipped with a respirator filter having a pleated tube and a coil tube on the respirator connector 10, which is a mask or tracheal intubation tube connected to a bag constituting an artificial respirator, so that bacteria and bacteria through secretions such as exhaled air, sputum, saliva, etc. There is a structural differentiation that eliminates various causes of infection transmission through a structure that removes viruses.

As described above, in the case of performing artificial respiration using a respiratory connector mounted on the respiratory tract after performing incubation and inserting an esophageal tube, the present invention exacerbates infection and infection through secretions that can be discharged through the respiratory connector. Prevent the spread of infection by taking special care and prevention of the outbreak.

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to the specific embodiment described above. That is, a person of ordinary skill in the technical field to which the present invention pertains can make a number of changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications It should be considered that equivalents are also within the scope of the present invention.

Claims (4)

A respirator connector 10 mounted on the patient's face to perform artificial respiration;
A bag 20 connected to one side of the branch pipe 12 configured to communicate with the respiratory connector 10; And
Includes; a filter module 100 connected to the other side of the branch pipe 12,
The filter module 100,
A connection port 110 directly coupled to the other side of the branch pipe 12,
Corrugated pipe 120 connected on the branch pipe 12 through the connection port 110,
The coil tube 130 disposed in the corrugated pipe 120 and
It includes a cover 150 coupled on the outside of the corrugated pipe 120,
The coil tube 130 has a built-in structure with villi for filtering impurities along the inner surface thereof,
Devices to prevent the transmission of artificial respiration infections.
The method of claim 1,
The filter module 100,
Further comprising a ring-type filter 140 connected to the coil tube 130,
Devices to prevent the transmission of artificial respiration infections.
The method of claim 1,
The corrugated pipe 120 is a translucent material,
Devices to prevent the transmission of artificial respiration infections.
delete

Images