阅读说明：本技术 致动器装置 (Actuator device ) 是由 钗安·钗斯·埃米达多明格斯 迈尔塔·拉格拉洛佩斯 卡罗琳娜·马丁尼兹贝纳 拉斐尔·胡利亚纳门德 于 2019-07-15 设计创作，主要内容包括：本发明涉及一种致动器装置,该致动器装置构造成用于在两个位置之间推动元件,使得在具有最大延伸的端部位置,施加的力受到限制,从而防止被推动的元件受到损坏。致动器装置特别设计成用于致动阀,该阀的打开或关闭取决于流体的温度,该流体例如是布置在内燃机的排气导管中的热回收器中所使用的液体冷却剂。(The present invention relates to an actuator device configured for pushing an element between two positions, such that in an end position with maximum extension, the force applied is limited, thereby preventing the pushed element from being damaged. The actuator device is designed in particular for actuating a valve, the opening or closing of which depends on the temperature of a fluid, for example a liquid coolant used in a recuperator arranged in an exhaust conduit of an internal combustion engine.)

1. An actuator arrangement (A) for actuating a linear displacement, the actuator arrangement (A) comprising:

-a main pole (1);

-a first chamber (3), the first chamber (3) containing a substance (4), the specific volume of the substance (4) changing upon a change in temperature, the first chamber (3) being configured to be in thermal contact with a heat source;

-an inner rod (2), said inner rod (2) projecting from said first chamber (3) and being movable along an axial direction (X-X') to exert a driving force in response to a volume change of said substance (4) contained in said first chamber (3);

-a first base (5), said first base (5) being adapted to be pushed by said inner rod (2) and being movable along said axial direction (X-X '), wherein said main rod (1) is movable along said axial direction (X-X ') and attached at or near an end to a second base (10), wherein said second base (10) is movable along said axial direction (X-X ');

-an inner supporting surface (8.1), said inner supporting surface (8.1) being attached to said first base (5) by means of a spacer element (8), said spacer element (8) spacing said inner supporting surface (8.1) from said first base (5) according to said axial direction (X-X'), wherein said inner supporting surface (8.1) limits the movement of said second base (10);

-a first spring (6), said first spring (6) having a first spring constant, said first spring (6) being positioned with one end supported on said first base (5) and the opposite end supported on said second base (10), so that said second base (10) can be moved closer to said first base (5) by means of compressing said first spring (6);

-a housing (9) attached to the first chamber (3) and housing the assembly formed by the first base (5) and the inner support surface (8.1) and the second base (10), wherein the housing (9) further houses a second spring (7) having a second spring constant, and wherein:

the second spring (7) is positioned with one end supported on the first base (5) and the opposite end supported on the housing (9) so that the first base (5) can move under the compression of the second spring (7) to restore the position of the first base (5) when the inner rod (2) no longer exerts any force.

2. The device according to claim 1, wherein the substance (4) has the following volume expansion coefficient: the volume expansion coefficient is such that the specific volume of the substance (4) increases at an increased temperature.

3. The device according to claim 2, wherein the substance (4) is: the specific volume of the substance increases mainly when it undergoes a phase change, the substance (4) preferably being a wax.

4. Device according to any one of the preceding claims, wherein the spacer element (8) is an inner bushing (8) housing the first spring (6), one end of the inner bushing (8) being attached to the first base (5) and the end opposite to the end attached to the first base (5) comprising the inner support surface (8.1).

5. Device according to claim 4, wherein the inner bushing (8) comprises a peripheral flange (8.2) at one end, and the inner bushing (8) is attached to the first base (5) by means of the peripheral flange (8.2), and the second spring (7) is supported on the first base (5) by means of the peripheral flange (8.2).

6. Device according to any one of the preceding claims, wherein at least the first chamber (3), the inner rod (2), the first base (5), the second base (10), the spacer element (8), the first spring (6) and the second spring (7) form an assembly housed in the casing (9), said assembly being held in position by means of the closure of the casing (9).

7. The device according to any one of the preceding claims, wherein the housing (9) of the actuator comprises a second chamber (9.4) housing the first chamber (3) and a fluid inlet (9.2) and a fluid outlet (9.3) for the passage of a fluid, such that the substance (4) housed in the first chamber (3) is in thermal communication with the fluid passing through the second chamber (9.4).

8. Device according to claim 7, wherein the second chamber (9.4) is separated from all the parts displaced by the action of the inner rod (2) by means of a closed ring (9.4.1).

9. The device according to any one of the preceding claims, wherein the casing (9) is closed by a seat (9.5) guiding the axial movement (X-X') of the main rod (1).

10. A valve (V) comprising:

-a flap (11), the flap (11) being movable between two end positions so as to close a first seat (18) or a second seat (19), in a first end position the first seat (18) being open and the second seat being closed, in a second end position the first seat (18) being closed and the second seat being open, wherein the flap (11) is actuated by an actuator device (a) according to any one of the preceding claims, such that:

-the main lever (1) of the actuator device (a) moves the flap (11) between its end positions, and

-once the flap (11) reaches the second end position, an additional displacement of the inner rod (2) of the actuator (a) for closing the first seat (18) causes the first spring (6) to be at least partially compressed and the first base (5) and the second base (10) to move closer to each other in the actuator (a).

11. Valve (V) according to claim 10, wherein the flap (11) is pivoted around the axis (12) at a first angle (a) corresponding to the first end position₁) And a second angle (alpha) corresponding to said second end position₂) Wherein the shaft (12) is attached to the main rod (1) of the actuator device (a) by means of a cam (13), the cam (1) being rotatably movable3) -converting a linear displacement of the main lever (1) into a rotation of the shaft (12).

12. Valve (V) according to claim 10 or 11, wherein the first seat (18) and the second seat (19) are configured as portions made of stamped and bent sheet metal.

13. A heat recovery device (R) comprising:

-an exhaust conduit (14), the exhaust conduit (14) being for passing hot exhaust gases;

-a heat exchanger (15), the heat exchanger (15) being for heat exchange between hot exhaust gas and a coolant fluid, the heat exchanger (15) comprising a conduit (15.1) for the passage of hot gas and a conduit (15.2) for the passage of coolant fluid, wherein:

-the duct (15.1) for passing gas through the heat exchanger (15) is in a bypass configuration with the exhaust duct (14);

-a valve (V) according to any of claims 10 to 12 for establishing the passage of hot gases through the exhaust duct (14) or through the duct (15.1) for passing gases through the heat exchanger (15), so that:

-in a first end position of the valve (V), the hot gas passes through the heat exchanger (15) and

-in a second end position of the valve (V), the hot gas passes through the exhaust duct (14);

wherein the coolant fluid passing through the conduit (15.2) for the passage of coolant fluid is in thermal communication with the chamber (3) of the actuator means (A) of the valve (V).

14. The recuperator (R) of claim 13, wherein said second chamber (9.4) is in fluid communication with said coolant fluid by means of a coolant fluid inlet (9.2) and a coolant fluid outlet (9.3) of said housing (9), such that the opening of said valve (V) is dependent on the temperature of said coolant fluid.

15. The recuperator (R) of any of claims 13 or 14, wherein said actuator (a) comprises a manifold, preferably a tubular metal plate, at said coolant fluid inlet (9.2) and said coolant fluid outlet (9.3).

16. An internal combustion engine comprising a heat recuperator (R) according to any one of claims 13 to 15.

Technical Field

The present invention relates to an actuator device configured to push an element between two positions, such that in an end position of the actuator element having a maximum extension, the force applied is limited, thereby preventing damage to the pushed element.

The actuator device is particularly designed for actuating the following valves: the opening or closing of the valve depends on the temperature of the fluid, for example the liquid coolant used in a recuperator arranged in the exhaust gas duct of the internal combustion engine.

Background

Actuators, and in particular linear actuators, are devices that can be controlled from the outside such that a rod is linearly displaced to move other devices or elements in turn.

This movement may be controlled to enable the rod to be positioned in both end positions, or may also allow a degree of adjustment to allow the rod to be positioned in an intermediate position as well.

One very widely used type of actuator is a pneumatic actuator, in which a rod is attached to a piston that is pushed by pressurized gas. If the piston receives pressurized gas on one of its surfaces, the rod moves in one direction, and if the piston receives pressurized gas on the opposite surface, the rod moves in the opposite direction. This type of actuator is controlled by a valve which allows pressurised gas to enter a specific chamber closed by a piston.

Another very widely used type of actuator is based on the use of electrically energized solenoids. In this case, the pushing is caused by a magnetic field generated by the current flowing through the solenoid, wherein the magnetic field interacts with a permanent magnet attached to the rod.

The following actuators are also known: the actuator is based on a volume change of a substance, such as wax, in particular when a change from a solid phase to a liquid phase occurs. The volume in the liquid phase increases significantly, so that if wax is stored in a chamber enclosed by the piston, the piston is displaced by the increase in volume.

An advantage of this type of actuator is that the composition of the wax can be determined such that the phase change occurs at the target temperature.

This is the case for valves that must be activated when a predetermined temperature is reached.

Nevertheless, these actuators have the problem that in the solid state, the wax is a nearly incompressible fluid, so that the displacement of the piston or rod when the phase change of the wax occurs depends almost entirely on the change of its volume, thereby exerting the force necessary for this expansion to occur.

When the actuator moves the closing element of the valve, if the closing element has reached the closed state before the displacement corresponding to the end position of the actuator, the actuator will move forward as it is due to the expansion of the wax, in which case it may even damage or destroy the valve or the mechanism of the actuator.

To prevent such damage, in the prior art, the closed position is adjusted to a position close to but short of the closed state. In other words, it remains partially open so as to have a margin to prevent damage due to the additional expansion of the substance.

As a result, it is not completely closed in order to protect the valve, leaving an unavoidable minimum flow. Such a flow through the opening present in the partial closure in the closed position is disadvantageous for the correct operation of the system comprising the valve configured in this way. For example, undesirable overheating, pressure drop, etc. of the liquid coolant occurs in the heat recovery system.

The present invention solves this problem by including a pressure limiting element so that the actuator can be adjusted such that it allows full closure of the valve without damage due to excessive displacement of the actuator arrangement.

Disclosure of Invention

A first aspect of the invention is an actuator arrangement having a linearly displaceable rod and comprising a portion limiting the maximum pressure exerted by the actuator in its end position.

The actuator device comprises at least:

-a main pole;

-a first chamber containing the following substances: the specific volume of the substance changes under the condition of temperature change, and the first chamber is configured to be in thermal contact with a heat source;

-an inner rod emerging from the first chamber and movable in an axial direction to exert a driving force in response to a volume change of the substance contained in the first chamber.

The main rod is a rod that moves according to an axial direction, and is configured to move or push elements of other devices or other elements, for example, the main rod opens and closes a valve.

In another aspect, there is a chamber containing a substance, the volume of which varies with temperature, and the chamber being in thermal contact with a heat source to cause a change in temperature. The temperature change causes a change in the specific volume of the substance, which causes an axial displacement of the inner rod. The displacement of the inner rod is responsive to a change in volume of the substance contained in the chamber, and the inner rod is an internal pushing element of the actuator device.

The inner rod also moves according to the axial direction.

The apparatus further comprises:

-a first base adapted to be pushed by the inner rod and movable in an axial direction, wherein the main rod is movable in the axial direction and attached to a second base at or near an end, wherein the second base is movable in the axial direction;

-an inner support surface attached to a first base by means of a spacer element spacing the inner support surface from the first base according to an axial direction, wherein the inner support surface limits the movement of a second base;

a first spring having a first spring constant, wherein one end is supported on the first base and the opposite end is supported on the second base, such that the second base can be moved close to the first base by compressing the first spring.

The inner rod pushes the first base during its displacement. The two components do not have to be attached to each other; indeed, in one embodiment, when the inner rod is fully retracted into the first chamber, there is a gap or margin between the inner rod and the first base. When the inner rod starts to displace, due to the expansion of said substance, out of the first chamber, the inner rod first contacts the first seat and they displace together in the remaining course.

Thus, the first base is associated with the movement of the inner rod. In another aspect, the primary shaft is attached to the second base. A first spring is located between the two bases, so that the displacement of the inner rod from the first base is transmitted by means of said spring to the second base and thus to the main rod.

The spring constant of the first spring is calibrated such that the spring maintains its maximum extension and acts like a rigid solid in the main path of the main bar.

The maximum extension of the first spring is limited by the maximum spacing between the first and second bases. The movement of the second base is limited by support on an inner support surface attached to the first base by means of a spacer element. In other words, the second base may be moved closer to and separated from the first base, but this separation does not exceed the separation set by the position of the inner support surface.

The apparatus also has the following components:

a housing attached to the first chamber and housing an assembly formed by the first base and the inner support surface and the second base, wherein the housing further houses a second spring having a second spring constant, and wherein:

the second spring is positioned with one end supported on the first base and the opposite end supported on the housing such that the first base can move under the compression of the second spring to restore the position of the first base when the inner rod no longer applies any force.

The actuator device moves the main rod in one direction as a result of the pushing of an inner rod which transmits pressure to the main rod by means of a first spring which acts like a rigid solid. The position is restored by means of a second spring which is gradually compressed under the push of the inner rod. When the inner rod no longer exerts any force, the energy stored in the second spring causes movement in the opposite direction.

One end of the second spring is supported on the first base and the other end is supported on the housing. The second spring can be supported on the first base by means of the interposition of a seat or, as in the preferred example to be described below, by means of a peripheral flange of the spacer element between the internal support surface and the first base.

When the actuator pushes the main rod, the position corresponding to the stroke end position can be reached because the inner rod is pushed by the volume expansion of the substance. This end-of-travel position of the main lever does not mean the end-of-travel position of the inner lever, which can continue to move. In this case, the displacement of the main lever is stopped, and the first base and the second base are moved close to each other by compressing the first spring. If the first spring has a spring constant such that the force generated on the primary lever does not exceed the maximum pressure allowed by the means by which the actuator is moved in its end-of-travel position, the mechanisms of both the actuator and the second means are not subject to any damage.

The spring constant of the first spring is set to limit the maximum pressure exerted by the actuator on the main lever.

The spring constant of the second spring is set to ensure the return of the retracted position of the first base when the pushing of the inner lever is no longer present. The first elastic constant and the second elastic constant may be different, and each of them is set according to the function of each spring.

Another object of the invention is a valve actuated by an actuator device such as one of the mentioned. The valve has a seat closed by a flap moved by an actuator. When the flap reaches its position closing the seat, if the inner rod of the actuator continues to move forward, the pressure exerted on the flap is limited, preventing damage to the components of the valve, the actuator or both.

Another object of the invention is a recuperator comprising a heat exchanger in a bypass configuration with an exhaust conduit of an internal combustion engine. Exhaust gas is circulated through the exhaust conduit. The assembly formed by the heat exchanger and the exhaust conduit further comprises a valve such as one of those described. The valve has two end positions, one for circulating the exhaust gas through the heat exchanger to recover heat from the exhaust gas that would otherwise ultimately be discharged to the atmosphere or directly through the exhaust conduit without passing through the heat exchanger.

If the temperature of the liquid coolant reaches a predetermined temperature, it is advisable to shut off the exhaust gas flow through the exchanger by means of a valve to close the passage to the exchanger and leave the passage through the exhaust duct unaffected. Therefore, heat is no longer transferred to the heat exchanger, and the temperature of the liquid coolant is prevented from further increasing. According to one embodiment, the actuator has a chamber in which a temperature-dependent volume of the substance is stored in thermal communication with the liquid coolant of the heat exchanger, such that the temperature of the liquid coolant also determines the temperature of the substance and the position of the valve.

According to a preferred example, the substance is a wax and it changes from a solid state to a liquid state when the temperature rises, causing a significant expansion, resulting in the extension of the actuator stem. The protrusion of the main rod closes the passage of hot gas to the heat exchanger, thereby preventing the temperature of the liquid coolant from increasing further.

Drawings

These and other features and advantages of the present invention will become clearer based on the following detailed description of a preferred embodiment, given purely by way of illustrative and non-limiting example, with reference to the accompanying drawings.

Fig. 1, 2 and 3 show a preferred example of an actuator and a cross-section of the flap according to a longitudinal section, allowing to see the most representative three positions depending on the extension of the actuator.

Fig. 4 shows a perspective view of an actuator according to an embodiment attached to a flap of a valve, wherein only two seats are seen.

Fig. 5 shows the same embodiment of the actuator, which is shown in perspective view and is held by means of a clamp that allows the position of the actuator to be adjusted according to the longitudinal direction of the main actuating rod of the actuator.

Fig. 6, 7 and 8 show an embodiment in which the actuator and the valve actuated by the actuator are mounted in a heat exchanger. The three different figures show the position of the valve and its actuated position in an enlarged detail view and a cross-sectional view of the actuator.

Detailed Description

According to a first aspect thereof, the present invention relates to an actuator device for actuating a linear displacement, which actuator device allows to actuate a valve, for example between its open and closed positions.

Fig. 1, 2 and 3 show a preferred example of an actuator a according to a longitudinal section and according to three different operating positions.

The actuator a shown in fig. 1 is a preferred example of the present invention. This preferred example is formed by a housing 9 having a substantially cylindrical configuration and two sections of different diameters-a first narrower section comprising most of the components of the actuator a and a second section of larger diameter comprising those components in contact with the liquid cooling liquid. In this embodiment, the change in diameter allows the internal components to be assembled by insertion, and the sealed closure separates the main internal components from the area of contact with the liquid coolant.

According to another embodiment, the actuator a shows a constant diameter of the housing 9 along its length.

The liquid coolant is mentioned because in a preferred example to be described below, the liquid coolant is used as a heat source for initiating the displacement of the actuator a. However, the actuator may be activated with any other type of fluid or heat source.

Inside the housing 9, in the section with the larger diameter, there is a first chamber 3 comprising a substance 4, the specific volume of which substance 4 can be changed in the event of a temperature change. In this preferred embodiment, the substance used is a wax, wherein wax is understood to be a substance formed from long-chain fatty acid esters and alcohols also having a long chain, which wax is hard under cold conditions and generally soft and plastic under the application of heat. Most importantly, when these substances melt, they transform from a solid to a liquid state, the specific volume increases significantly, and these substances offer very low compressibility. These properties make them very good motivating substances by means of phase changes caused by heating. Reference numeral 4 will also be used hereinafter for the wax.

The first chamber 3 partially houses the inner rod 2. When the specific volume of the wax 4 increases, the increase in specific volume pushes the inner rod 2 out.

The configuration of the housing 9, the distribution of the internal components and the main movement of the parts depend on the axial direction which will be identified as X-X'.

In this case, the inner rod 2 springs out according to the axial direction X-X' and acts as an element for pushing the actuator a.

The housing 9 has a second chamber 9.4, through which second chamber 9.4 the liquid coolant of the combustion engine circulates, which liquid coolant increases its temperature by means of a heat exchanger 15 with heat from the exhaust gases. In the operating mode, the liquid coolant circulating through the second chamber 9.4 is in thermal communication with the first chamber 3 to allow heat to be transferred between the liquid coolant contained in the second chamber 9.4 and the wax 4. The temperature of the wax 4 therefore tends to be the temperature of the fluid located in the second chamber 9.4.

In the second section with the larger diameter in which the second chamber 9.4 is located, there is a coolant fluid inlet 9.2 and a coolant fluid outlet 9.3 allowing flow through the second chamber 9.4.

The second chamber 9.4 has a closure ring 9.4.1 for fixing the position of the first chamber 3 and for establishing a seal by additionally using an O-ring, not shown in the drawings, with a component arranged on the other side.

In the orientation shown in fig. 1, there is a closure cap 9.1 above the second chamber 9.4. In the stage of insertion of the internal components of the actuator a, the closing ring 9.4.1 is fitted in the step of the transition between the section with larger diameter and the section with smaller diameter of the casing 9.

The inner rod 2, which is pushed by means of the increase in the specific volume of the wax 4, moves out of the displacement according to the axial direction X-X' through the sealing closure 3.1 of the first chamber 3. The sealing closure 3.1 is attached to the inner surface of the housing 9.

In this embodiment, the inner rod 2 has a circular end with which the inner rod 2 pushes the first base 5. The first base 5 is configured as a transverse plate having a seat 5.1 for receiving the rounded end of the inner rod 2.

In this embodiment, the seat 5.1 of the first base 5 is not attached to the end of the inner rod 2. This allows separation between them to be possible, for example because there is a certain margin when the inner rod 2 is fully retracted.

When the actuator a is viewed from the outside, the moving element is the main rod 1, which main rod 1 acts as the main pushing element intended to move another device, such as a valve V.

The main bar 1 has an end on the outside with a head 1.2, this head 1.2 being configured to be coupled to an element which it must move. In this particular case, the head is a shell arranged transversely to the axial direction X-X' allowing the entry of the driving pin 16. The opposite end of the boom 1 is attached to a second base 10.

The device comprises a first spring 6 between the first base 5 and the second base 10, which first spring 6 transmits the movement of the inner rod 2 to the primary rod 1. The spring constant of the first spring 6 is sufficiently high to transmit motion in the operating mode without having to compress this first spring 6, but at least in the case of an excessive pressure of the main lever 1, the spring compresses so as to prevent the main lever 1 from being displaced-out of the housing, even if the inner lever 2 continues to move out of the first chamber 3.

The second base 10 can be axially displaced relative to the first base 5 by means of compression or extension of the first spring 6. The first and second bases 5, 10 are spaced apart but the maximum spacing is limited by the inner support surface 8.1 which limits the maximum spacing of the second base 10. The inner support surface 8.1 is spaced from the first base 5 by means of a spacer element, which in this embodiment is configured in the form of a cylindrical bushing 8.

The cylindrical bushing 8 shows at one end a base with a perforation for the passage of the main stem 1. The inner surface of the base is the inner support surface 8.1. In this embodiment, the opposite end of the cylindrical bushing 8 shows a peripheral flange 8.2 attached to the first base 5.

Thus, the first spring 6 and the second base 10 are housed inside the cylindrical bush 8, and the axial movement of both elements 6, 10 takes place in this cylindrical bush 8.

The housing 9 is closed by a seat 9.5 guiding the axial movement X-X' of the main rod 1.

The second spring 7 is accommodated in a housing 9, wherein one end of the second spring 7 is supported on the first base 5 and the other end is supported on a seat 9.5 of the housing 9. In this particular embodiment, the seat in the first base 5 is created by the intervention of a peripheral flange 8.2 of a bush 8, this bush 8 being attached to the first base 5, wherein the flange 8.2 acts like the seat of the second spring 7 and the bush 8 acts like the inner guide of the second spring 7 and the outer guide of the first spring 6.

The function of this second spring 7 is to restore the initial position of the first base 5 when the inner rod 2 is no longer pushed by the wax 4.

The elastic constant of the second spring 7 may be different from the elastic constant of the first spring 6.

When the inner rod 2 is retracted, the construction of the actuator a is similar to that shown in fig. 1, although in this embodiment the initial margin between the inner rod 2 and the seat 5.1 of the first bottom 5 is not shown. Both the first spring 6 and the second spring 7 are at maximum extension.

As the temperature of the wax 4 increases, the wax 4 will undergo a change of state with an increasing specific volume, causing the inner rod 2 to move out.

The removed inner rod 2 pushes the axial displacement of the first base part 5, which first base part 5 in turn transmits a force in the axial direction X-X' to the first spring 6 and the second spring 7.

Since one end of the second spring 7 is supported on a seat 9.5 attached to the outer casing 9, the force transmitted to said second spring 7 causes it to deform elastically, compressing it and storing elastic energy that will allow the restoration of said initial position corresponding to the position before the inner rod 2 is moved out.

As long as the primary lever 1 is not constrained during its displacement, the force transmitted to the first spring 6 causes the displacement of the second base 10, and therefore the extension of the primary lever 1, as long as said second base 10 is supported on the inner supporting surface 8.1 of the bushing 8.

According to the embodiment shown in fig. 1, 2 and 3, at least the first chamber 3, the inner rod 2, the first base 5, the second base 10, the spacer element 8, the first spring 6 and the second spring 7 form an assembly housed in the housing 9, which assembly is held in place by closure of the housing 9 by means of the lid 9.1.

According to another embodiment, the housing 9 is formed by the attachment of a plurality of parts.

Fig. 2 shows the following positions: in which the main lever 1 is displaced by the inner lever 2 with the interposition of a first spring 6, wherein this first spring 6 exhibits the same degree of extension as before the displacement takes place. In contrast, the second spring 7 is positively compressed due to such movement of the first base 5.

Fig. 1 and 2 show a cross-sectional view of a flap 11, the flap 11 being pivoted about an axis 12 by means of a cam 13, a pin 16 being fixed to the cam 13. The pin 16 is located in the housing of the head 1.2 of the boom 1.

Thus, the axial displacement of the main rod 1 forces the flap 11 to rotate.

Fig. 1 shows the position of the unextended primary lever 1, which results in a first angle α of the flap 11₁Fig. 2 shows the extended position of the boom 1, which results in a second angle α of the flap 11₂Second angle α in this embodiment₂Greater than the first angle alpha₁。

Flap 11 is part of a valve V, even if valve V is not depicted in fig. 1 to 3, the first angle α of flap 11₁And a second angle alpha₂Corresponding to a first position of the valve V, in which the first seat 18 of the valve V is open, and a second position, in which the first seat 18 of the valve V is closed.

Fig. 4 shows a flap 11 of a valve V according to an embodiment, the position of which flap 11, according to the perspective view, opens a first seat 18 of the valve V on the left, wherein the valve V is shown without closing its chamber elements, so that the interior of the valve V can be seen. The perspective view also shows the actuator a and the elements belonging to the kinematic chain between the actuator a and the flap 11. The angle alpha is an angle that increases in the direction shown in fig. 4.

In this position of actuator a, flap 11 closes second seat 19, which is located on the right in fig. 4. The force for closing this second seat 19 is exerted by a second spring 7, this second spring 7 being responsible for reaching the retracted position of the main lever 1.

After the actuator a is extended, the flap 11 moves from the second seat 19, on the right in fig. 4, to the first seat 18, on the left in fig. 4.

Once flap 11 closes first seat 18, primary lever 1 cannot move forward any more without causing damage to any part making up the kinematic chain, or to seat 18 of the valve, or even to actuator a. However, the specific volume of the wax 4 may continue to increase and the axial displacement of the inner rod 2 does not stop since the wax 4 is an incompressible fluid.

Fig. 3 shows the position of the components of the actuator a when the inner rod 2 continues to move forward after the first seat 18 is closed. Flap 11 still maintains second angle α₂But the first base 5 is displaced along its axial direction by X-X', which moves closer to the second base 10 at the expense of the elastic deformation of the first spring 6. This deformation of the first spring 6 prevents damage that may occur if the inner lever 2 pushed by the wax 4 is directly attached to the main lever 1.

In this embodiment there are two elements preventing damage to the springs 6, 7 of the actuator a.

The main rod 1 shows a flange 1.1 at the end, this flange 1.1 being housed inside the casing 9, so that in case of excessive displacement it will come into contact with the seat of the first base 5, limiting the maximum compression of the first spring 6. The distance of this flange 1.1 is calibrated so that the minimum distance that the inner supporting surface 8.1 of the bushing 8 must move in order to come closer to the seat in the first base 5 does not exceed the maximum deformation of the first spring 6.

The seat 9.5 guiding the displacement of the main rod 1 also has a support flange 9.5.1, which support flange 9.5.1 will also abut against the bush 8 in case of excessive displacement, limiting the maximum compression of the second spring 7 and also preventing accidental breakage of the second spring 7.

In this actuator a it is important to have the ability to adjust the position of the actuator a relative to the position of the shaft 12 of the flap, in order to determine the point at which the first spring 6 starts to compress in the operating mode, or the extent of compression or pre-loading of the second spring 7 after it has been restored to its position, for example by extension, in the operating mode.

According to one embodiment, the actuator a is fixed by means of a clamp 17 located in the cylindrical portion of the casing 9 to adjust its position according to the axial direction X-X'. The clamp 17 is tightened once positioned according to the axial direction X-X', which makes it possible to ensure, for example, the complete closing of the first seat 18 of the valve V and the minimum compression of the first spring 6. Another regulation criterion is also to ensure the complete closure of the second seat 19 of the valve V and the minimum compression of the second spring 7.

The advantage of fixing the actuator a by means of the clamp 17 is that it is easy to replace or exchange the actuator a without having to modify or change the remaining elements moved by the actuator a.

An example of a need to replace actuator a is when actuator a is damaged. In this case, it would only be necessary to open the clamp 17 and release the connection between the main bar 1 and the device moved by the actuator a, so that the actuator a is released and can be replaced by another actuator a.

Another example illustrating the advantage of being fixed by means of the clamp 17 is when the assembly formed by the actuator a and the device moved by the actuator a, for example the valve V, is manufactured according to different specifications. In this case, the assembly allows the actuator a to be interchanged without having to change the device moved by the actuator a.

According to another embodiment, the attachment of the actuator a is optionally achieved by means of a releasable fixing element, which is not necessarily formed by the clamp 17, i.e. which is an element that also allows the actuator a to be interchangeable.

Another object of the invention is a combination of a valve and an actuator a. According to one embodiment, the valve V comprises a flap 11, which flap 11 is displaceable between two end positions, a first open position in which the seat is open, which in the operating mode allows a flow passage, and a second closed position in which the seat 18 is closed, which in the operating mode prevents a flow passage, wherein the flap 11 is actuated by an actuator a according to an embodiment such as one of the above, such that:

the main bar 1 of the actuator device a moves the flap 11 between its end positions, and

once flap 11 reaches its closed position closing first seat 18, the additional displacement of inner rod 2 of actuator a for closing flap 11 causes first spring 6 to compress at least partially and first base 5 and second base 10 to move closer to each other.

The valve V according to this embodiment has a second seat 19, which second seat 19 closes when the main rod 1 of the actuator a is retracted. Thus, in the first end position of flap 11:

the first seat 18 of the valve is open,

the second seat 19 of the valve is closed, and

the main stem 1 of the valve is retracted.

Likewise, in the second end position of flap 11:

the first seat 18 of the valve is closed,

the second seat 19 of the valve is open, and

the main stem 1 of the valve is extended.

In the example shown in the figures, flap 11 is rotatable about axis 12 at a first angle α₁At a second angle alpha₂Is moved by the first angle alpha₁The second angle alpha corresponds to the first end position of the flap 11₂Corresponding to a second end position of the flap 11, in which the shaft 12 is attached to the main lever 1 of the actuator device a by means of a cam 13, which cam 13 converts the linear displacement of the main lever 1 into a rotation of the shaft 12.

One of the most interesting applications is a heat recovery device R for recovering heat from the gas flowing through the exhaust duct 14, which would otherwise eventually be injected into the atmosphere.

Fig. 6, 7 and 8 show the heat recuperator R according to this embodiment on the right and the actuator a on the left in cross-sectional detail with the position shown in fig. 1, 2 and 3, respectively. In the details of the actuator, flap 11 has been removed to allow a more detailed view of the internal elements.

The heat recovery device R includes:

an exhaust duct 14, the exhaust duct 14 being intended to let hot exhaust gases pass;

a heat exchanger 15 for heat exchange between the hot exhaust gases and the coolant fluid, the heat exchanger 15 comprising a duct 15.1 for the passage of hot gases and a duct 15.2 for the passage of the coolant fluid, wherein:

the duct 15.1 for passing the gas through the heat exchanger 15 is in a bypass configuration with the exhaust duct 14;

the valve V is used to establish a passage for the hot gases through the exhaust duct 14 or through the duct 15.1 for passing the gases through the heat exchanger 15, so that:

in the first position of the valve V, the hot gas passes through the heat exchanger 15, and

in the second position of the actuated valve V, hot gas passes through the exhaust duct 14;

wherein the coolant fluid passing through the conduit 15.2 for the passage of the coolant fluid is in thermal communication with the chamber 3 of the actuator means of the valve V.

In fig. 6, the actuator a shows the main rod 1 retracted, keeping the position of the flap 11 of the valve V at the first angle α₁Wherein the flow circulation through the exhaust duct 14 is interrupted and the gas is allowed to flow to the heat exchanger 15 in a bypass configuration. In this position, heat from the exhaust gas is at least partially released to the liquid coolant circulating through the heat exchanger 15. The inflow and outflow of hot exhaust gas is indicated by hollow arrows, and the inflow and outflow of liquid coolant is indicated by solid arrows.

The temperature of the liquid coolant is gradually increased until the following temperatures are reached: it is undesirable for the liquid coolant to retain the recovered heat at this temperature. The wax 4 is selected so that its solid-liquid phase change temperature is at the limit temperature of the liquid coolant or at a lower predetermined temperature to account for the response time of the actuator a.

Liquid, method for producing the same and use thereofThe coolant is routed through the second chamber 9.4 so that when the temperature of the liquid coolant reaches a maximum predetermined temperature, the wax 4 changes or has changed phase, resulting in the extension of the inner rod 2 as shown in figure 7. The extension of the inner rod 2 pushes the main rod 1 to change the position of the turning plate 11 to a second angle alpha₂Wherein the first seat 18 of the valve for access to the heat exchanger 15 is closed and the second seat 19 is open, leaving the passage through the exhaust duct 14 unaffected. Thus, the heat exchanger 15 no longer transfers heat from the exhaust gas to the liquid coolant, thereby preventing the temperature of the liquid coolant from rising above the maximum allowable temperature.

However, the wax 4 may continue to expand. According to the invention, the actuator a compensates for the removed inner rod 2 by means of the compression of the first spring 6 as shown in fig. 8, thereby preventing damage that would result from over-expansion. The valve V maintains the closed position of the first seat 18 without causing damage thereto.

According to this embodiment, the recuperator R comprises an actuator a having manifolds made in the tubular metal plate at the coolant fluid inlet 9.2 and the coolant fluid outlet 9.3. According to other embodiments, the fluid inlet manifold, the fluid outlet manifold or both are realized by means of windows made in the casing 9.

In the embodiment described, the seats 18, 19 of the valve V are constructed from a metal plate that is stamped and bent to form two angled planes, as shown in fig. 4. For example, the resulting portion is machined to allow the passage of the shaft 12 of the flap 11 at the intersection of the two planes.

By this particular configuration, the body of the valve V is obtained which is cheap and has completely flat seats 18, 19. The chamber of the valve V is formed by closing the space with an outer body constituted by means of a stamped metal plate adapted to the part comprising the seats 18, 19.