WO2021219906A1 - Electromechanically actuated ventilator - Google Patents

Abstract

Disclosed is an electromechanically or manually actuated ventilator comprising: a frame (1) containing an electric motor (7) connected to a transmission shaft (18) to which a connecting rod (15) is joined, the free end of the connecting rod having a tracking roller (19) that makes contact with an actuation arm (11), the actuation arm being connected at one end by a hinged joint (12) and connected by a spring (2) to the support frame (1). A manual resuscitator or self-inflating bag (3) provided with an air inlet and an air outlet is disposed below the actuation arm (11), the circular movement of the connecting rod (15), by means of the actuation roller (19), being converted into a lifting and lowering movement of the actuating arm (11). This low-cost, easy-to-produce ventilator can operate automatically and adjustably and can also be manually actuated.

Description

ELECTROMECHANICALLY ACTUATED RESPIRATOR

DESCRIPTION OBJECT OF THE INVENTION

It is the object of the present invention, as the title of the invention establishes, an electromechanically actuated respirator, more precisely refers to a low-cost and easy-to-manufacture respirator for supply to hospitals and medical vehicles in case of illnesses. pandemic respiratory diseases.

The present invention is characterized by the special design and configuration of each and every one of the parts that make up the respirator, which makes it an easy element to manufacture at a low cost that can be activated manually or automatically.

Therefore, the present invention is circumscribed within the scope of respirators.

BACKGROUND OF THE INVENTION

Traditional respirators are used to help patients increase their blood oxygen levels. Traditional respirators are very expensive and complex equipment that is often in short supply due to these problems.

It is recognized that it would be advantageous to develop a simple, low-cost respirator that allows governments and hospitals to purchase large quantities in the event of a pandemic. It would also be very advantageous to design a simple respirator that allows untrained people to be able to manufacture a respirator on site if the need arises. Therefore, there is a need in the field for novel respirators that are inexpensive and easy to manufacture in the event of a pandemic.

Therefore, it is the object of the present invention to develop a simple, low-cost respirator such as the one described below and it is reflected in its essentiality in the first claim.

DESCRIPTION OF THE INVENTION

The object of the present invention is an electromechanically actuated respirator that is simple to manufacture and of low cost that allows governments and hospitals to purchase large quantities in the event of a pandemic.

According to one embodiment thereof, the present disclosure provides the simplest configuration for a medical respirator that is capable of providing adequate airflow, inspiratory / expiratory ratio, and that provides positive pressure at the end of expiration.

The respirator object of the invention is capable of using ambient air or oxygen at low pressure, it is also capable of operating with external energy sources, with batteries, as well as by means of a manual operation.

The electromechanically actuated respirator object of the invention comprises a support frame and housing of the elements that are part of it.

Inside the support frame or frame an electric motor is connected to a transmission shaft by means of a flexible coupling where the shaft of The transmission is supported by bearings, attached to the transmission shaft is a connecting rod, which at its free end has a tracking roller that contacts an actuating arm where this actuating arm is attached at one end by means of an articular joint and is attached by means of a spring to the support frame, being placed under the actuating arm a manual resuscitator or self-inflating bag provided with an air inlet and an outlet valve connected to a hose that can be connected to medical equipment, where the movement The circular movement of the connecting rod by means of the drive roller is transformed into a raising and lowering movement of the drive arm and therefore filling and emptying of the manual resuscitator or self-inflating bag and consequently producing an effect similar to that of inspiration and expiration.

The electric motor is in connection with a motor controller by means of a wiring so that it is possible to regulate the speed of rotation of the actuating arm and therefore of the actuating arm and consequently the speed of inspiration and expiration.

Additionally, in the event of a power outage or electromechanical failure of the device, an optical and / or acoustic alarm self-powered by the battery or electrical network is activated, in turn, activated by a fault detection sensor that is also self-powered.

The respirator can be powered by the electrical network, by its own battery or another external power source such as a photovoltaic panel, a domestic wind turbine or another car or moped battery.

The respirator object of the invention is not intended exclusively for hospitals but also for remote places where there is no other resource to keep a person alive until another team or help with greater benefits arrives. The respirator is very low cost since it is new design does not include complex components but seeks maximum simplicity and reliability without the need for maintenance.

Thanks to the characteristics described, an electromechanically actuated respirator easy to manufacture and with low costs is achieved that can operate automatically and adjustable, as well as can be manually operated in the event of a power failure.

Unless otherwise indicated, all technical and scientific elements used herein have the meanings commonly understood by one of ordinary skill in the art to which this invention pertains. Methods and materials similar or equivalent to those described herein can be used in the practice of the present invention. Throughout the description and the claims the word "comprise" and its variants are not intended to exclude other technical characteristics, additives, components or steps. For those skilled in the art, other objects, advantages and characteristics of the invention will emerge in part from the description and in part from the practice of the invention.

EXPLANATION OF THE FIGURES

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to a preferred example of a practical embodiment thereof, a set of drawings is attached as an integral part of said description. where by way of illustration and not limitation, the following has been represented.

In figure 1, we can see a front view of the electromechanically actuated respirator object of the invention. In figure 2, we can see a side view of the electromechanically actuated respirator object of the invention.

Figure 3 shows the kinematics and internal movement of an electromechanically actuated respirator.

PREFERRED EMBODIMENT OF THE INVENTION.

In view of the figures, a preferred embodiment of the proposed invention is described below.

In figure 1 we can see that the electromechanical actuator respirator object of the invention is supported by a structure or frame (1) which in turn facilitates transport and storage.

The respirator comprises an electric motor (7) that is coupled to a flexible coupling (17) to allow small misalignments with the transmission shaft (18), which is supported by bearings (16). This arrangement protects the output shaft in the motor (7) from any lateral load when the connecting rod (15) is rotated, since otherwise the connecting rod (15) would be directly connected to the output shaft of the motor (7) and it will inevitably drive the lateral load of the motor output shaft (7).

The connecting rod (15) at its free end has a roller (19) that contacts the drive arm (11) so that the motor rotation (7) is transmitted to the connecting rod (15) and this to the roller (19 ) and in turn said roller (19) when being in contact with the actuating arm produces a partial and cyclical rotational movement with respect to the axis (12). The actuating arm (11) produces a raising and lowering movement of a manual resuscitator or self-inflating bag (3) to which the air enters at one end and leaves through an outlet valve (4) that provides a adequate positive pressure at the end of expiration connected to a standard medical equipment hose (5).

The motor (7) has a control unit (8) that allows to control the r.p.m. (7) and thus achieve the desired breaths per minute. The control unit (8) is connected through the electrical wiring (10) to the motor (7), as well as to the electrical power supply (6) by means of an electrical wiring (9) and in case of having a battery ( 24) to this one.

In the event of a power outage or electromechanical failure of the device, a self-powered optical and / or acoustic alarm (22) is activated activated by a self-powered fault detection sensor (23)

Figure 2 shows a side view of the electromechanically actuated breather where the connecting rod (15) coupled to the transmission shaft (18) produces a rotary movement of the roller (19) that is attached to the connecting rod (15). Therefore, while the roller (19) follows a circular pattern driven by the connecting rod (15), it pushes and pulls the drive arm (11). The actuating arm (11) follows a partially circular and cyclical movement up and down driven by the roller (19) as it is articulated with the joint (12), acting and compressing the manual-resuscitator or self-inflating bag (3).

The drive arm (11) is spring-attached (2) to the frame (1) and helps the drive arm (11) to be in constant contact with the roller (19).

In the event of a power outage, the connecting rod (15) can be disconnected from the drive shaft (18), and the drive arm (11) can be manually operated by hand, mimicking electric drive. The kinematics established by this specific design arrangement, the position and dimensions of the actuation arm (11), roller (19), actuation arm (11) and linkage (2) allow the respirator to deliver the volumes of desired air, as well as the time and the ratio of the inspiratory and expiratory levels.

Figure 3 represents the kinematics and internal movement of an electromechanically actuated breather where the connecting rod (15) coupled to the transmission shaft (18), produces a rotary movement of the roller (19) attached to the connecting rod (15) in the side opposite the transmission shaft (18). Therefore, while the roller (19) follows a circular pattern driven by the connecting rod (15), it pushes and pulls the drive arm (11). The actuating arm (11) makes a cyclical up and down movement driven by the roller (19) and rotates with respect to the joint (12), acting and compressing the manual-resuscitator or self-inflating bag (3).

The spring (2) helps the drive arm (11) to be in constant contact with the roller (19).

The kinematics established by this specific design arrangement, together with the position and dimensions of the connecting rod (15), the roller (19), the drive arm (11) and the link (12), allow this invention to produce the desired results. Regarding volumes and air flow, as well as the timing and relationship of the inspiratory and expiratory cycles. The air volume is set by the amount of compression of the manual-resuscitator or self-inflating bag (3) and can be adjusted by moving the manual-resuscitator or self-inflating bag (3) from position (13) to position (14) (Figure 2) or other alternative positions so that the amount of compression of the resuscitator-manual or self-inflating bag (3) by the actuating arm (11) is less.

In addition, by modifying the dimensions of the connecting rod (15), and the distance between the joint (12) and the driving shaft (18), the inspiratory cycle (21) as well as the cycle expiratory (20), can be adjusted and therefore produce different inspiratory to expiratory ratios.

Having sufficiently described the nature of the present invention, as well as the manner of putting it into practice, it is stated that, within its essentiality, it may be carried out in other embodiments that differ in detail from that indicated by way of example. , and to which the protection sought will also be achieved, provided that it does not alter, change or modify its fundamental principle.

Claims

1 Electromechanically or manually operated respirator characterized in that it comprises a support frame (1) and housing of the elements that are part of it, so that an electric motor (7) is housed within the support frame (1) or frame connected to a transmission shaft (18) by means of a flexible coupling (17) where the transmission shaft (18) is supported by bearings (16), joined to the transmission shaft (18) is a connecting rod (15) that in Its free end has a tracking roller (19) that contacts a drive arm (11) where this drive arm is joined at one end by an articular joint (12) and is joined by a spring (2) to the frame (1) of support, being placed under the actuating arm (11) a manual resuscitator or self-inflating bag (3) provided with an air inlet and an outlet valve (4) connected to a connectable hose (5) to a medical team, where the movement circulates The end of the connecting rod (15) by means of the actuating roller (19) is transformed into a raising and lowering movement of the actuating arm (11) and therefore filling and emptying of the manual resuscitator or self-inflating bag (3 ) and consequently producing an effect similar to inspiration and expiration.

2. Electromechanically actuated respirator according to claim 1, characterized in that the electric motor (7) is in connection with a motor controller (8) by means of a wiring (10) so that it is possible to regulate the rotational speed of the connecting rod (15). ) and therefore of the actuating arm (11) and consequently the inspiration and expiration speed.

3.- Electromechanically actuated respirator according to claim 1 or 2, characterized in that the manual-resuscitator or self-inflating bag (3) is positionable from position (13) to position (14)

4. Electromechanically actuated respirator according to claim 1 or 2 or 3 characterized in that the electric motor (7) is in connection with an electrical power source (6) by means of an electrical wiring (9).

5.- Electromechanically actuated respirator according to any of the preceding claims, characterized in that the respirator is powered by the electrical network or by its own battery (24) or by another external power source such as a photovoltaic panel, domestic wind turbine or other external car battery or a moped.