ES2756873B2 - HIGH SENSITIVITY DOUBLE CLAP ANTI-RETURN VALVE - Google Patents

Description

DESCRIPTION

HIGH SENSITIVITY DOUBLE CLAPPER ANTI-RETURN VALVE

OBJECT OF THE INVENTION

The present invention refers to a highly sensitive double-flap non-return valve, designed to control the transfer of air between a control volume and the exterior, in such a way that that control volume and the exterior are precisely connected by means of the valve of the invention, which is equipped with two orifices that communicate with the outside and another two that communicate with the control volume. One of these holes is always an outlet and the other is always an inlet.

The valve of the invention is applicable in different sectors such as underwater, rescue, toxic atmospheres, pumping fluids, assisted breathing, valves for sanitary use and others.

The object of the invention is to provide a highly sensitive non-return valve in its operation, which is not affected in said operation by gravity, nor does it require elastic elements that require minimum pressure levels maintained for its correct operation.

BACKGROUND OF THE INVENTION

The non-return valves currently on the market require a pressure gradient to activate their opening, so that in order to close it, the disappearance or inversion of such pressure gradient is necessary.

In this sense, there are non-return valves that work gravitationally, so that they store energy or are blocked when there is a pressure gradient, and are released when said gradient ceases. These valves have elements that rise and return to their initial position when the pressure gradient disappears.

Oscillating flap valves store elastic energy, having elements such as springs or diaphragms that allow their operation without depending on gravity as in the case described above.

However, in this type of valve, the pressure gradient must be kept above the elastic resistance offered by the material.

In another group of non-return valves, there are piston or ball valves which, in addition to being affected by gravity, can be additionally assisted by elastic elements such as springs, with the limitations previously described.

In any of the cases the valves described are structurally complex and, most importantly, their reliability and operation is limited by a minimum maintained pressure gradient that must at all times overcome the gravity or elasticity of a material in order to actuate.

DESCRIPTION OF THE INVENTION

The highly sensitive double-flap non-return valve, which is recommended, presents a series of characteristics that solve the problems of conventional non-return valves, resulting in a simple, more precise valve, with lower pressure gradients and that does not need maintain the gradient to keep the valve actuated.

For this, and more specifically, the valve of the invention is constituted from a base body in which two holes are established for the location of the clappers that are mounted on the same shaft, the ends of which are supported by the respective covers, inside and outside, of the base body itself.

The flaps can rotate both clockwise and anti-clockwise, always jointly and severally to add the forces, so that both in one direction and in the other one of the flaps performs, for example, the closure of the entrance hole from the outside to the control volume, allowing the exit through the outlet orifice, or allowing the entrance of the outside to the control volume, closing the outlet of it and opening the inlet orifice. In all cases the fluid inlet from the outside to the control volume is performed through the inlet port and the fluid outlet from the control volume is performed through the outlet port.

The operating principle of the valve is based on the pressure difference between the control volume and the external pressure, so that when the external pressure is greater than the pressure within the control volume, the clappers that make up the closing mechanism rotate a certain angle in an anti-clockwise direction, allowing the entry of the fluid through the inlet and blocking the entry of fluid from the outlet, while when the external pressure is less than the pressure within the control volume, then the closure system rotates a certain angle in a clockwise direction, allowing the fluid to exit towards the outlet port and blocking the outlet of the fluid to the inlet port.

In this way, a non-return valve is achieved with a high sensitivity in its operation, which is not affected in its operation by gravity, nor does it require elastic elements that limit the pressure or minimum pressure levels for its correct operation. In addition to not requiring a sustained pressure gradient for the valve to maintain its state, either opening or closing.

DESCRIPTION OF THE DRAWINGS

To complement the description that is going to be made below and with the aim of helping 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, with an illustrative and non-limiting nature, the following has been represented:

Figure 1.- Shows an exploded perspective view of a high-sensitivity double-flap non-return valve, made in accordance with the object of the present invention.

Figure 2.- Shows a transparent view of the assembly of the previous figure duly assembled.

Figure 3.- Shows a schematic detail of the first clapper that participates in the valve of the invention.

Figure 4.- Shows a schematic detail of the second clapper that participates in the valve of the invention.

Figure 5.- Shows a perspective view of the valve during the intake process.

Figure 5B.- Shows a schematic view of the valve in the intake maneuver.

Figure 6.- Shows a view similar to that of figure 5, but corresponding to the expulsion process.

Figure 6B.- Shows a view similar to that of figure 5B, but corresponding to the expulsion process.

Figures 7-7B.- Show schematic and detailed views of the air inlet flow in the inlet position.

Figures 8-8B.- They show both schematic and detailed views of the blocking of the air inlet flow through the outlet mouth.

Figures 9-9B.- They show respective schematic and detailed views of the blockage of the outlet flow through the inlet mouth.

Figures 10-10B.- Show schematic and detailed views of the air outlet flow in the ejection position.

PREFERRED EMBODIMENT OF THE INVENTION

In view of the figures outlined, it can be seen how the high-sensitivity double-flap non-return valve object of the present application comprises a base body (1), with two covers, an outer cover (2) and an inner cover (3), base body (1) inside which two clappers (4,5) are mounted, which can rotate with respect to a common axis (6) to which both they are joint, said flaps (4,5) being out of phase with each other.

More specifically, in the base body (1), chambers are defined on either side of it in which the clappers (4,5) play, and which are closed by means of the outer (2) and inner (3) covers. ), chambers that communicate with each other through a central hole (1 ') through which the central and cylindrical body (4'-5') of both clappers (4,5) is tightly passed.

In this way, the first clapper (4) associated with the face and consequently the outer cover (2) of the device communicates through the inner hollow of its central and cylindrical body (4 ') with the inlet mouth (10) provided for the valve, acting as a communication link with the second clapper (5) through the hole in its central and cylindrical body (5 '), which has holes (5' ') that communicate the inlet mouth (10) with the inner chamber of the main body (1) in which conduits are defined to a control volume (8), a control volume (8) that will also communicate with the outer chamber of the main body (1) in which the first clapper (4), and in which pipes are defined that communicate with respective outlet openings (9) provided in the outer cover (2).

Thus, the phase shift between flaps (4,5) is such that when the second flap (5) is in the open position, that is, allowing the admission of fluid through the inlet port (10) towards the control volume (8), the first clapper (4) blocks the outlet of said control volume towards the outlet ports (9).

In figure 3 the second clapper (5) is shown and in figure 4 the first clapper (4), so that in correspondence with the central core (5 ') of the second clapper (5) the inlet mouth is established (10) towards the corresponding control volume (8) established in the valve body (1) itself, so that, returning again to figure 4, the first clapper (4) is capable of turning an angle a by which the control volume (8) is communicated with the respective outlet ports (9), or it is rotated in an anti-clockwise direction to block said control volume (8).

Thus, and as shown schematically in figure 5B, when the pressure outside the outlet (9) is greater than the pressure inside the control volume (8) then the closing mechanism rotates an angle a in an anti-clockwise direction, allowing the entry of fluid from the inlet port (10), and blocking the entry of fluid from the outlet port.

On the other hand, when the external pressure, that is to say in the outlet mouth (9), is less than the pressure inside the control volume, then the closing mechanism rotates an angle a in a clockwise direction, allowing the outlet of the fluid contained in the control volume (8) towards the outlet port (9), as shown in figure 6B.

The device thus described always absorbs the fluid through the inlet port (10) and expels it through the outlet port (9), preventing the fluid from leaving the inlet port (10) and the fluid entering through the outlet mouth (9).

Schematic representations of fluid intake and outlet operation are shown in Figures 7, 8, 9 and 10.

Thus, in figure 7 the air inlet flow is shown in the intake position and in figure 8 the air inlet flow blockage through the outlet mouth is shown.

That is, when the external pressure in the inlet port (10) is greater than the pressure in the control volume (8), the position of the second clapper (5) allows the entry of fluid through the inlet port ( 10), while in figure 8 it can be seen how when the external pressure in the outlet mouth (9) is greater than the pressure in the control volume (8), then the position of the first clapper (4) prevents the fluid inlet through the outlet (9).

However, in Figures 9 and 10, the outlet flow blockage is shown through the inlet port (10) and the air outlet in the expulsion position, respectively. That is, when the external pressure in the inlet mouth (10) is lower than the pressure in the control volume (8), then the second clapper (5) prevents the fluid from leaving the inlet mouth (10) , whereas when the external pressure in the outlet (9) is less than the pressure in the control volume (8), then the position of the first clapper (4) allows the fluid to exit through the outlet (9).

In this way, a highly sensitive valve is achieved, since the pressure difference between the control volume and the exterior that operates the double flap is very low, to which must be added the fact that the only support point of the control mechanism closing are the ends of the shaft, the weight being very low, the mechanism being perfectly balanced.

Although and as previously mentioned, the valve thus described can have multiple applications, one of said applications could be breathing in toxic atmospheres, in the absence of oxygen or under water, so that, by adding a second control volume, Fog problems could be solved in helmets in which this type of valve would be implantable to control the user's breathing.

Claims (1)

1a.- High sensitivity double clapper non-return valve, characterized in that it is made up of a base body (1), with two covers, an outer cover (2) and an inner cover (3), base body (1 ) inside which two flaps (4,5) are mounted, which can rotate with respect to a common axis (6) to which both are integral, said flaps (4,5) being out of phase with each other; having provided that in the base body (1) chambers are defined on either side of the same in which the clappers (4,5) play, chambers that are closed by means of the outer (2) and inner (3) covers, and that they communicate with each other through a central hole (1 ') through which the central and cylindrical body (4'-5') of both clappers (4,5) is tightly passed, with the particularity that the The first clapper (4) associated with the face and outer cover (2) of the device communicates through the inner hollow of its central and cylindrical body (4 ') with an inlet mouth (10), acting as a communication link with the second clapper (5) through the hole of its central and cylindrical body (5 '), which has one or more holes (5' ') that communicate the inlet mouth (10) with the chamber associated with the inside face of the main body (1) in which pipes are defined to a control volume (8), control volume (8) that communicates with the outer chamber of the main body (1) in which the first clapper (4) plays, outer chamber in which pipes are defined that communicate with at least one outlet mouth (9), preferably two, provided in the outer cover (2), all this in such a way that when the second clapper (5) is in the open position, that is to say allowing the admission of fluid through the inlet mouth (10) towards the control volume (8), the first clapper (4) block the outlet of said control volume towards the outlet ports (9).