ES2879644A2 - Actuator device for axial fan gate - Google Patents

Abstract

An actuator device for an axial fan gate comprising a frame, which can be attached to a fan structure that includes a gate with two halves, which can fold centrally in the fan structure, an actuator means, for example, linear or rotary, coupled to respective first ends of connecting rods, and second ends of the connecting rods are coupled to each gate half via guide-type connection means.

Description

DESCRIPTION

ACTUATING DEVICE FOR AXIAL FAN DOOR

TECHNICAL FIELD OF THE INVENTION

The present invention is included in the field of ventilation devices, of those used to ventilate industrial facilities or buildings, for example, where livestock operations are carried out, such as farms for the reproduction and raising of chickens, pigs, or other types of livestock. .

Specifically, the invention relates to a device that makes it possible to operate a damper comprising two halves that can be hinged towards each other to open the duct of the axial fan that they regulate.

BACKGROUND OF THE INVENTION

As is known, industrial facilities or structures, for example, livestock farms, use ventilation systems to maintain a given environment, guaranteeing a supply of fresh air and removing undesirable odors and / or gases, for example, carbon dioxide (CO ² ), emitted by the animals in the facility.

These ventilation systems can include various ventilation devices, for example axial fans that displace the volumes of air required to maintain the desired environment.

These fans are provided with a gate with two hinged halves that close the ventilation duct when the fan propeller is not working, and open said duct to allow the extraction of air when the propeller is working.

Commonly, the opening and closing of the gate halves is done as follows: when the fan begins to extract air, the air flow pushes the gate halves and causes them to open; then when the fan is stops, the return of the gate halves to their closed position is carried out by the action of two springs attached to each of said halves.

The known solutions, despite their convenience in not requiring any external drive to open and close the damper, with the consequent energy savings, have the disadvantage that, for a low speed of rotation of the fan propeller, the flow of In this case, the extracted air is not enough to push the damper halves, and as a result, it is not possible to open them completely, which causes an obstruction of the ventilation duct that reduces the performance of the fan. .

For this reason, it is necessary to design, in a simple and economical way, a device that allows to operate the damper of an axial fan, in such a way that it overcomes the previous drawback or disadvantage.

DESCRIPTION OF THE INVENTION

The present invention is established and characterized in the independent claim, while the dependent claims describe other characteristics thereof.

The object of the invention is an actuator device for an axial fan damper. The technical problem to be solved is how to achieve the complete opening of the damper even at low speeds of the rotation of the fan propeller.

The device comprises a frame, which can be attached to a fan frame that includes a gate with two hinged halves centrally on the fan frame.

Furthermore, the device comprises an actuator means, for example, linear or rotary, coupled to the respective first ends of some connecting rods, where second ends of the connecting rods are coupled to each half of the gate through joining means of the type guide.

Where, the actuating means can be electrically, pneumatically or hydraulically actuated. Thus, the actuation at two different moments of the actuator means on the respective connecting rods in turn causes the second ends of the connecting rods to actuate the guide-type joining means in such a way that, at first, they produce the opening of the halves. gate, and in a second moment, cause it to close.

Thus, it is possible to achieve the opening and closing of the damper independently of the speed of rotation of the fan propeller, with which, even when said speed is low, the total opening of the damper halves is achieved, without these latter block the ventilation duct. In other words, it is avoided that the hatch halves do not open fully due to the depression caused by other fans or the opposition of the wind, since with the exposed device the total opening of the hatch halves is always guaranteed, with total effectiveness, despite the effects of depression or wind. Likewise, both the total and partial opening of the gate halves is guaranteed by a certain percentage, for example, half, to be able to generate pressure when the air speed is not high and does not allow air to enter.

BRIEF DESCRIPTION OF THE FIGURES

The present specification is complemented with a set of figures, illustrative of the preferred example, and never limiting of the invention.

Figure 1 represents a perspective view of a first embodiment of the device object of the present invention, with linear actuator means, coupled to an axial fan.

Figure 2 represents a perspective view of the first embodiment of the device of the present invention, in its gate opening position.

Figure 3 represents an enlarged detail of Figure 2, without the hatch halves.

Figure 4 represents a top view of the device of Figure 2, without the frame and in an intermediate position of the gate.

Figure 5 represents a top view of the device of Figure 2, in its closed position of the gate.

Figure 6 represents an enlarged perspective view of a second embodiment of the device object of the present invention, with a rotary actuator means.

Figure 7 represents a bottom perspective view of the device of Figure 6, without the frame and without the hatch halves.

Figure 8 represents a schematic top view of a first possible embodiment of the gear transmission of the rotary actuator means of the device of Figures 6 and 7.

Figure 9 represents a front schematic view of a second possible embodiment of the gear transmission of the rotary actuator means of the device of Figures 6 and 7.

DETAILED EXHIBITION OF THE INVENTION

The present invention is an axial fan damper actuator device.

As shown in figures 1 and 6, the device comprises a frame (1), which can be fixed to a fan structure (2), only in figure 1, which includes a gate (3) of two halves (3.1, 3.2), the latter, centrally folding in the fan structure (2). The frame (1) can be attached to the structure of the fan (2), either, in a horizontal position, as is the case of a first embodiment shown in figure 1, or, in a vertical position, such as in a second embodiment shown in figure 6.

Advantageously, the device can be arranged, protected and hidden, between the propellers (2.1) of the fan (2) and the damper (3).

Additionally, the device comprises an actuator means (4, 8). As shown in Figures 1 to 5, in the first preferred embodiment, said actuator means is a linear actuator means (4), for example, electrically, pneumatically or hydraulically actuated. Where, the ends (4.1, 4.2) of the linear actuator means (4) are coupled in an articulated manner to the respective first ends (5.1) of some connecting rods (5) which, in this first embodiment of the device, are pivotally arranged in the frame (1). Preferably, each end (4.1, 4.2) of the linear actuator means (4) is coupled to the first end (5.1) of the corresponding connecting rod (5) by means of a pin (7). See figure 3.

Likewise, the connecting rods (5) comprise second ends (5.2) coupled to each half (3.1, 3.2) of the gate (3) through a guide-type joining means (6), that is, a type of sliding joint between two elements, where a first element of the joint is adapted to slide internally or externally in a second element of said joint that serves as a guide and fastening to the first, or vice versa.

Preferably, the guide type joining means (6) are at least one sheave (6.1) adapted to run through a guide channel (6.2), where the sheave (6.1) is coupled to the second end (5.2) of the connecting rod (5) and the guide channel (6.2) is fixed to the corresponding half (3.1, 3.2) of the gate (3).

Likewise, as shown in figure 4, it is preferred that the guide channel (6.2) comprises at least one length that covers from a closed position of the gate (3) to a fully open position of said gate (3). In other words, that the roller (6.1) can run through the guide channel (6.2) between a first stop end (6.21), corresponding to the fully open position of the gate (3), and a second stop end ( 6.22), which corresponds to the closed position of the gate (3).

Thus, when the actuation of the linear actuator means (4) causes its ends (4.1,4.2) to unfold, see figure 4, the latter make the connecting rods (5) pivot at their respective pivot points (5.3), rotating in opposite directions, that is, said connecting rods (5) approach, which causes the sheaves (6.1), coupled to the second ends (5.2) of both connecting rods (5), to roll through the respective guide channels ( 6.2), from the second stop end (6.22) to the first end stop (6.21), making the halves (3.1, 3.2) of the gate (3) approach each other, until reaching the total opening of the gate (3), seen in figure 2.

In this way, it is guaranteed that the damper (3) is completely open during the operation of the fan (2), even when its propellers (2.1) rotate at low speeds.

When it is required to close the gate (3), since the fan (2) stops working, then again the linear actuator means (4) is activated, this time, causing its ends (4.1, 4.2) to be collected, these Last, they make the connecting rods (5) pivot again at their respective pivot points (5.3), rotating in opposite directions at the previous time, that is, said connecting rods (5) move away, which causes the sheaves ( 6.1) coupled to the second ends (5.2) of both connecting rods (5) roll through the respective guide channels (6.2), from the first stop end (6.21) to the second stop end (6.22), making the halves (3.1, 3.2) of the gate (3) also move away from each other, until reaching the total closure of the gate (3), seen in figure 5.

Likewise, in a second embodiment of the equally preferred device, shown in Figures 6 to 9, instead of the linear actuator means (4), the device comprises a rotary actuator means (8), the latter also being able to be electrically, pneumatically or hydraulically actuated.

As in the first embodiment, as shown in Figures 6 and 7, the rotary actuator means (8) is coupled to the first ends (5.1) of the connecting rods (5), and the second ends (5.2) of said connecting rods (5) are coupled to each half (3.1, 3.2) of the gate (3) through the guide type joining means (6).

As shown in figure 7, in particular, the rotary actuator means (8) comprises respective output shafts (8.1, 8.2), which are rigidly fixed to the first ends (5.1) of the connecting rods (5), in such a way that, when the output shafts (8.1, 8.2) rotate, the connecting rods (5) rotate in the same way, that is, in the same direction of rotation of the corresponding output shaft (8.1, 8.2).

Additionally, the rotary actuator means (8) comprises an input shaft (8.3) and a gear transmission (8.4) adapted to convert a rotational movement of the input shaft (8.3) into rotational movements of the output shafts (8.1, 8.2) in opposite directions to each other, figures 8 and 9. For example, the rotational movement of the input shaft (8.3) can be supplied by an electric motor (9), figures 6 and 7.

As shown in figure 8, in a first preferred embodiment of the rotary actuator means (8), the gear transmission (8.4) of the latter comprises a pinion (8.41) fixed concentrically to the input shaft (8.3), and respective wheels toothed (8.42, 8.43), which share the same module and number of teeth, and are concentrically fixed to the output shafts (8.1, 8.2); where, the pinion (8.41) is suitable to mesh with one of the toothed wheels (8.42, 8.43) and the toothed wheels (8.42, 8.43) are suitable to mesh with each other, and in turn, the relationship between the number of teeth of the pinion (8.41) and toothed wheels (8.42, 8.43) is selected in such a way that it allows to achieve a torque and an actuation speed of the device suitable to effectively cause the opening and closing of the halves (3.1, 3.2) of the gate (3).

In another possible embodiment of the rotary actuator means (8), shown in figure 9, the gear transmission (8.4) comprises two toothed wheels (8.42, 8.43), which also share the same module and number of teeth, and are fixed concentrically to the output shafts (8.1, 8.2); However, in this possible embodiment, there is no pinion (8.41) and the input shaft (8.3) is concentrically fixed to one of the sprockets (8.42, 8.43), where the sprockets (8.42, 8.43) are also meshed each.

It can be understood that, in this last embodiment of the rotary actuator means (8), the input shaft (8.3) shares the axis of rotation with one of the output shafts (8.1, 8.2), and the actuation source, for example, the electric motor (9), directly drives one of the output shafts (8.1, 8.2) of the toothed wheels (8.42, 8.43). Therefore, this embodiment would be possible as long as the turning speed and the torque delivered by said motor (9) are adjusted to the torque and drive speed of the device suitable to effectively cause the opening and closing of the halves (3.1, 3.2 ) of the damper (3).

In the same way, as shown in figure 6, the connecting rods (5) comprise their second ends (5.2) coupled to each half (3.1, 3.2) of the gate (3) through a guide-type joining means ( 6), such as those described above for the first embodiment of the device.

Thus, when the actuation of the rotary actuator means (8) entails the rotation of the input shaft (8.3) in a first direction (represented in figure 8), by means of the transmission of gears (8.4), it is achieved that the output shafts (8.1, 8.2) rotate in opposite directions, making the connecting rods (5) move closer together, which causes the sheaves (6.1), coupled to the second ends (5.2) of both connecting rods (5), to roll by the respective guide channels (6.2), from the second stop end (6.22) to the first stop end (6.21), making the halves (3.1, 3.2) of the gate (3) move closer to each other, until reaching the total opening of the gate (3), as happens in the extreme position of the first embodiment of the device shown in figure 2.

In the same way as in the first embodiment, it is guaranteed that the damper (3) is fully open during the operation of the fan (2), even when its propellers (2.1) rotate at low speeds.

When it is required to close the gate (3), since the fan (2) stops working, again the rotary actuator means (8) is actuated, this time, to cause a rotation of its input shaft (8.3) in the opposite direction. to the previous one, where, by means of the transmission of gears (8.4), it is achieved that the output shafts (8.1, 8.2) this time rotate in the opposite directions to the previous time (represented in figure 9), making the connecting rods (5 ) move away from each other, which causes the sheaves (6.1), coupled to the second ends (5.2) of both connecting rods (5), to roll through the respective guide channels (6.2), from the first butt end (6.21 ) until the second end stop (6.22), causing the halves (3.1, 3.2) of the gate (3) to also move away from each other, until reaching the total closure of the gate (3), as happens in the extreme position of the first embodiment of the device shown in figure 5.

As can be understood, in all the embodiments, the rotation in both directions of the halves (3.1, 3.2) of the gate (3) is limited by the respective first stop end (6.21) and second stop end (6.22), allowing to regulate the travel of the opening and closing of both halves (3.1, 3.2) of the gate (3). For this, preferably, the first and second stop ends (6.21, 6.22) of the guide channel (6.2) may comprise respective end-of-stroke sensor means (not shown in the figures), which, when detecting the sheave in its position (6.1), stop the actuation of the linear actuator means (4) or the rotary actuator means (8) as appropriate. Or, the end-of-stroke control can be achieved by using a timer means (not shown in the figures), through which the actuation time of the actuator means (4, 8) is regulated both in opening and closing. of the halves (3.1, 3.2) of the gate (3). Or, this end can also be achieved by monitoring the consumption of the fan (2) (it increases at the top).

One option, applicable to the two embodiments set forth, is that when the actuator means (4, 8) is electrically actuated, specifically a direct current motor powered by at least one battery. In this way, compared to what is known in the state of the art of an alternating current motor powered by the electrical network that moves the propellers and the air pressure opens the halves of the gate, and what happens when the electric current falls (power supply failure) the motor stops and normally each half of the damper closes by incorporating recovery springs, with the option of the direct current motor there is the additional advantage of avoiding such a closing effect, since the Batteries power said DC motor even when there is no power in the electrical network, that is, the motor is powered during the opening and closing movement, since the associated electronics, discussed in the next paragraph, detects the electrical network failure and feeds the actuator (4, 8) with the batteries, opening the halves (3.1, 3.2) of the gate (3) in the event of a power supply failure, thus providing an "anti-asphyx system ia ”by guaranteeing air flow under all circumstances.

Another detail of the invention, not shown, is that an electronic board is included that controls the actuator means (4, 8) and that allows the total or partial opening of each half (3.1, 3.2) of the gate (3) in any percentage. In turn, said electronic board communicates with a climate controller which is the one that determines the opening percentage and air flow (propeller revolutions (2.1)) based on an algorithm and environmental sensors (temperature, humidity, ...).

Claims (11)

1. - Actuator device for axial fan damper, comprising a frame (1) that can be fixed to a fan structure (2) that includes a damper (3) of two halves (3.1, 3.2) centrally folding in the structure fan (2), an actuator means (4, 8) coupled to the respective first ends (5.1) of some connecting rods (5), and second ends (5.2) of the connecting rods (5) are coupled to each half (3.1, 3.2) of the gate (3), characterized in that the second ends (5.2) of the connecting rods (5) are coupled to each half (3.1, 3.2) of the gate (3) through guide-type joining means (6). 2. - Device according to claim 1, in which the actuating means is a linear actuating means (4) with respective ends (4.1, 4.2) that are coupled in an articulated manner to the first ends (5.1) of the connecting rods (5) , and the connecting rods (5) are pivotally arranged on the frame (1). 3. - Device according to claim 2, in which each end (4.1, 4.2) of the linear actuator means (4) is coupled to the first end (5.1) of the corresponding connecting rod (5) by means of a pin (7). 4. - Device according to claim 1, in which the actuator means is a rotary actuator (8) with respective output shafts (8.1, 8.2) that are fixed to the first ends (5.1) of the connecting rods (5). 5. - Device according to claim 4, in which the rotary actuator means (8) comprises an input shaft (8.3) and a gear transmission (8.4) adapted to convert a rotational movement of the input shaft (8.3) into respective rotational movements of the output shafts (8.1, 8.2) in opposite directions to each other. 6. - Device according to claim 5, in which the gear transmission (8.4) comprises a pinion (8.41) fixed concentrically to the input shaft (8.3), and respective toothed wheels (8.42, 8.43), which share the same module and number of teeth, fixed concentrically to the output shafts (8.1, 8.2), where the pinion (8.41) meshes with one of the sprockets (8.42, 8.43) and the sprockets (8.42, 8.43) are meshed with each other . 7. - Device according to claim 5, in which the gear transmission (8.4) comprises two toothed wheels (8.42, 8.43), which share the same module and number of teeth, fixed concentrically to the output shafts (8.1, 8.2 ), and the input shaft (8.3) is concentrically fixed to one of the sprockets (8.42, 8.43), where the sprockets (8.42, 8.43) are meshed with each other. 8. - Device according to claim 1, in which the guide type joining means (6) are at least one roller (6.1) adapted to run through a guide channel (6.2), where the roller (6.1) It is coupled to the second end (5.2) of the connecting rod (5) and the guide channel (6.2) is fixed to the corresponding half (3.1, 3.2) of the gate (3). 9. - Device according to claim 8, in which the guide channel (6.2) comprises a first stop end (6.21) and a second stop end (6.22), where the first stop end (6.21) corresponds to a position of total opening of the gate (3) and the second stop end (6.22) corresponds to a closed position of the gate (3). 10. - Device according to claim 1, in which the actuator means (4, 8) is electrically, pneumatically or hydraulically actuated. 11. - Device according to claim 10, wherein when the actuator means (4, 8) is electrically actuated it is a direct current motor powered by at least one battery.