BRMU8303705Y1 - mini pneumatic mechanical pulmonary ventilator - Google Patents

Abstract

"mini pneumatic mechanical lung ventilator". which basically comprises an astatic multi-vibrator driven from conventional pressurized gas sources such as oxygen or medical compressed air.

Description

"MINI PNEUMATIC MECHANICAL PULMONARY FAN".

TECHNICAL FIELD

This utility model refers to equipment for artificial ventilation in cases of respiratory failure.

TECHNICAL BACKGROUNDS

Pulmonary ventilators are used in hospitals and similar places. These devices, due to their complexity, present high costs, which limits their purchase by a larger number of users.

An example of a conventional pulmonary ventilator can be seen in US 4592349 (Bird), where a ventilator for use with a pressurized gas source for supplying such gas to the airway of a patient having an inlet adapted for use is illustrated. be connected to the gas source, and an outlet adapted to be connected to the patient's airway. The North American ventilator includes an oscillatory inspiratory phase generally consisting of a power control module, an oscillatory diffusion module, a shuttle service module, an oscillatory volumetric fan module, a fail-safe alarm, and a universal breathing circuit. In particular, a device referring to a device combining venturi system with exhalation valve is illustrated, however, the constructional features differ substantially from those disclosed in the present application.

Another document of the state of the art, developed by the applicant itself and already duly filed in Brazil and other countries, is the document BR PI 9903858 (Logomed) which deals with a device that operates to dilute and limit the pressure of various gases supplied. to a patient. The function of the apparatus may be described as a pressurized gas activated astatic multi-vibrator (for example, such as oxygen or medical compressed air). The original application BR PI9903858 has functional characteristics and objectives that essentially are the object of the present application. However, in view of the need for improvements in said device, the applicant developed technical-constructive improvements, which optimized the use of the device. since it provides a mechanism, in the form of a rubber pouch, which is used during cardiac massages.

BRIEF DESCRIPTION OF OBJECT The mini pneumatic mechanical fan differs from the others, not by its function, but precisely by its practical aspect, based on its simplicity of construction and mainly of operation, with low cost that allows its acquisition by entities and professionals. previously unable to acquire such important equipment. The emergence of this device allows a greater number of professionals and services to have an artificial ventilator, facilitating the care on the public road, in the transport of patients, completing the emergency unit and even in-hospital transport, and can replace with advantages. manual pulmonary ventilation, releasing a trained professional for other activities during the emergency.

This device is characterized by releasing a high flow (about 90 I per minute), while allowing to restrict the airway pressure within values accepted in the literature, below those causing barotrauma ie less than 35 cm water can be adjusted from 20 to 35 every 5 cm of water.

This is a modern concept of pulmonary ventilation called PCV (Pressure Control Ventilation). In practice, there is an automatic flow adjustment as a function of lung volume and airway resistance, adjusting the gas distribution in pulmonary intimacy. The volume that enters the lung is dependent on airway impedance. Once the set pressure is reached, flow is interrupted in units whose pressure has been in equilibrium with the pressure generated by the device, with residual flow remaining in units not yet filled, which drastically reduces the possibility of pulmonary rupture (volutrauma or barotrauma). .

This fan, despite its size, has several characteristics that make it unique in the category of ventilators for emergency care, removal or in-hospital transport such as: - Low gas consumption (2.5 I. per minute for any age group) , which guarantees great autonomy; - reduced size and weight; - Easy operation with only two controls: frequency and inspiratory pressure; - Safe use: The Venturi system used to dilute oxygen limits airway pressure and remains open throughout the breathing cycle, allowing the patient to breathe regardless of device cycling. The normal concentration of the device is 40% and can be enriched with additional 02; - Time-cycled and pressure-limited, which can be adjusted from 20 to 35 cm of water with variations of 5 cm of water; - Button for manual inspiration (when compressed performs a pulmonary insufflation); - Unpublished synchronizer for use in cardiac arrest, which allows when a cardiac massage is performed, the respirator ceases to cycle until the practitioner performs it, when the respirator then performs one or more pulmonary insufflations, stopping again. when the massage is restarted; - Constructed with non-magnetizable material, which allows its use in magnetic resonance rooms; - Patient circuit with a pathway and expiratory valve at its end, close to the patient; - Low cost; - Robustness.

Basically, the MECHANICAL PULMONARY PULMONARY FAN comprises an astatic multi-vibrator, driven from conventional pressurized gas sources such as oxygen or medical compressed air. For the construction of pulmonary ventilators, multi-vibrators, square wave generators are used. In the ventilator, the high phase of the wave corresponds to inspiration and its duration is called inspiratory time. The low phase corresponds to expiration and its duration is the expiratory time. The sum of these times corresponds to one respiratory cycle and the unit of time (1 minute) divided by this period defines the respiratory rate. Another parameter in artificial ventilation is the relationship between these times, called inspiration: expiration ratio (I: E ratio). Control of flow, pressure or inspiratory time allows control of the volume of gas that is introduced into the lung. To avoid mechanical trauma to the lungs due to excessive pressure, the ventilators must also have a pressure limiting or controlling system.

In the pneumatic mechanical mini lung ventilator these controls are simplified: Flow - During the inspiratory phase, a fixed flow passes through the injector which is amplified by the Venturi system, which allows its automatic adjustment, as previously described;

Airway pressure - The Venturi system is .1 designed to allow user to adjust inspiratory pressure from 20 to 35 cm of water;

Ratio I: E - is fixed between 1: 2 and 1: 2.5 during the assembly of the apparatus; Respiratory Rate Control - should be adjusted by the operator from 6 to 40 cycles per minute. To facilitate this operation, pictures of an infant, a child and an adult are printed next to the frequency control knob by simply matching the reference mark with the desired picture.

DESCRIPTION OF DRAWINGS

For a better understanding, the PNEUMATIC MECHANICAL PULMONARY FAN will be described based on figure 1, where it represents a schematic drawing of the apparatus. DETAILED OBJECT DESCRIPTION

According to the illustration cited the PNEUMATIC MECHANICAL PULMONARY FAN MINI consists of the following elements and works as follows: a pressurized gas source at 50 psi or 3.5 kgf per square centimeter (oxygen or medical compressed air) is connected to the circuit (1). The gas from it passes through the filter (2) and moves towards the O-ring type relief (3) in the center of the diaphragm (4) and moves it towards the chamber (5), communicating the lane (1) with lane (6), which runs towards a one-way valve (7) which runs in the direction of this flow and which follows it to lane 8. Thus, the gas from (1) follows the duct (8) in two directions: a) duct (9) - feeding the 0.5 mm diameter injector (10) which directs it to the diffuser (11), causing ambient air to be drawn through the holes ( 12 and 12a) generating up to 90 I per minute of a mixture of air and oxygen at the patient outlet (13) and b) duct (14) - to a needle valve (15) that controls its entry into the chamber (5 ). When the pressure in this chamber, added to the spring tension (16), produces a force greater than that exerted on the diaphragm by the pressure of the chamber (5A), it is forced downward, causing its central ring-shaped relief (3). ), seal the hole (1), ending the "on" phase, which corresponds to the inspiratory phase and beginning the phase and expiratory phase. As there is no further flow in (8), the gas that has accumulated in the chamber (5) is now moving in the opposite direction and slowly exits it through the same needle valve (15) into the atmosphere through the ductwork (14, 9) and injector (10). With this gas leak from chamber (5), its pressure drops progressively and when the force exerted by it on the diaphragm (4), added the tension of the spring (16) is less than the force exerted by the pressure of the gas of the fohte. From the central relief of the ring-shaped diaphragm (3), the source gas escapes into the chamber (5a - below the diaphragm), causing the force on the diaphragm to grow very rapidly, raising it sharply and communicating again. (1) and (8), initiating a new inspiratory phase.

As chamber (5) is filled and emptied by the same needle valve (15) and as the filling pressure tends to be constant (source pressure) and the emptying pressure tends to fall continuously during the phase and expiratory, the inspiratory time tends to be shorter than the expiratory time, which can be further adjusted higher or lower in direct proportion to the spring tension (16) through the threaded part (needle valve housing -15).

When the button (16) is pressed it pushes pin 17, which has two 0'Ring type rings to communicate the gas inlet port (1) with the Venturi system injector through port 18, thus allowing a pulmonary insufflation independent of fan cycles, called Manual Inspiration. As this flow also runs along lanes 9 and 8 and would tend to elevate diaphragm 4, one-way valve 7 is required. Part number 19 is a hard rubber pouch that is placed on the palm of a glove. When compressed, air from the interior is expelled through a conduit 20 towards valve 21 having a valve 22 which seals orifice 26 outwards and directs it to conduit 23 and thereafter 20a toward one-way valve 24, compressed by a spring (25). As the pressure of circuit 20a is greater than that of chamber 5, this valve opens and the pressure of this chamber rises and lowers diaphragm 4, inhibiting inspiration. While the bag is compressed, chamber pressure 5 does not drop and diaphragm 4 does not rise, keeping inspirations inhibited. Otherwise, the gas from chamber 5 escapes through the needle valve 15 into the Venturi system and from there into the external environment, starting a new inspiratory phase.

When the pouch 19 is decompressed, the pressure within it drops and air is drawn through the port 26 with the valve opening 21, refilling the pouch.

This mechanism is to be used during cardiac massages, when the glove containing the rubber pouch (19) is wedged in the hand that performs the massages, being compressed every time the heart is massaged. The assembly formed by the pouch (19), the valve (21) and the conduits 20 and 20a may be disconnected from the apparatus when not in use through connector 27.

As explained in this descriptive report, this appliance has the following advantages: A) It is designed in a monoblock, small size, which makes it much more resistant, easy to assemble, with reduced manufacturing cost and without empty spaces, where usually debris accumulates or dust, facilitating possible contamination; B) Its mechanism is all made of very simple mechanical design parts and materials that, despite their durability characteristics, are low cost, and can be manufactured by revolutionary machining or molding in plastic or rubber, making its cost very low; C) The same mechanism works, without moving parts with fine mechanical adjustment, which makes it invulnerable to shocks; no sliding friction, which prevents wear of its components and therefore more durable and less prone to failure; D) It has only one Venturi system at the outlet, which at the same time dilutes the pure oxygen from the source with atmospheric air to a 40% oxygen mixture and defines a pressure in the airway that can vary from 20 to 35 cm. water, which makes its use as safe as for barotraumas or the toxicity of high oxygen concentrations; inspiratory pressure variation is achieved only by adjusting the distance between the diffuser and the injector, requiring no additional parts; E) It has only two controls, making it easy to use in emergencies without the need for many user adjustments, while providing ease of handling by setting other ventilator parameters within safe limits: the frequency-which can be adjusted accordingly. 8 to 40 cpm and user-adjustable inspiratory pressure control from 20 to 35 with variations of 5 cm H20; F) Manual Inspiration - has a button on its side which, when pressed, allows a pulmonary inflation controlled by the attending physician, which facilitates the adaptation of agitated patients to the ventilator, without the use of AM6ÜS; G) Features an unprecedented system of synchronization of the respirator with cardiac massages, which causes the respirator to stop cycling when a chest compression is performed, preventing thoracic hyperpressure and dismissing a professional who would be responsible for patient ventilation; H) Low cost, due to its simple manufacturing and assembly characteristics, allowing its universal acquisition and, if convenient, even having a disposable version; I) Considering its use in emergencies, it has a "pneumatic" mechanism, which uses as the trigger source, the same pressurized gas that will be supplied to the patient, dispensing external power source, such as batteries, whose failure would be severe in an emergency situation. ; J) Very small size and weight, fitting in the adult palm, which facilitates its transport with the patient, be it in-hospital transport or in aid to victims of a burning building, for example. Its low weight and volume also make it easy to use in aircraft (helicopters and rescue aircraft) or even as a safety accessory in commercial flights, military activities, clubs, companies, etc .; K) Smooth cylindrical shape with stainless steel capsule, greatly facilitating its disinfection and preservation; L) Minimal internal and artificial airway compliance, may be used neonates, children and adults; M) Be made of non-magnetizable plastics and metals, which makes it usable in places with strong magnetic fields (anywhere in the MRI room).

CLAIM

Claims (1)

1) "MECHANICAL PNEUMATIC PULMONARY FAN", of a kind comprising a circuit (1) with filter (2) and a ring-shaped relief (3) provided at the center of the diaphragm (4); circuit (1) includes: chamber (5) communicating with track (1) through track (6); A one-way valve (7) allows gas to flow through the conduit (8) in two directions: through the conduit (9) feeding the injector (10) which directs it to the diffuser (11) and is drawn through the holes (12 and 12a) generating a mixture of air and oxygen at the patient outlet (13) and through the conduit (14) to a needle valve (15) which controls its entry into the chamber (5); spring (16) is provided which exerts pressure on the diaphragm as a function of chamber pressure (5A) allowing the ring-shaped relief (3) to seal the hole (1); characterized in that a hard rubber pouch (19) is provided which is placed on the palm of a glove and, when compressed, air from the interior is expelled through a conduit (20) towards the valve (21) having a valve (22) responsible for sealing orifice (26) to the outside and directing flow to the conduit (23) and thence (20a) towards the one-way valve (24), compressed by a spring (25); the assembly formed by the pocket (19), the valve (21) and the conduits (20) and (20a) can be disconnected from the apparatus through the connector (27).