Patent Description:
Within the scope of forming bodies of motor vehicles, it is known to use actuating units for the movement and the keeping in position of the metal sheets during the processing. Such mechanical processing operations require a highly accurate positioning of the elements to be processed and also for such positioning to be kept over time. For such a purpose, the actuating units comprise a closing device capable of bringing an actuating arm connected to such a device to an exact closed operating position and once reached, of keeping it in such a position, thus triggering an irreversibility mechanism capable of ensuring the position also in the absence of control, for example in the absence of compressed air in the case of pneumatic control.

Such actuating units can be mounted in any spatial orientation, so that it is not always guaranteed that the actuating unit is capable of stably maintaining its opening position. In fact, in such a position the actuating arm is free to move, e.g., under the action of gravity.

In order to ensure that the open position of the actuating arm is maintained irrespective of the spatial orientation according to which the actuating unit has been mounted, it is known to equip actuating units with self-retaining groups mounted outside the body of the unit, generally consisting of a pair of complementary retaining elements which engage each other when the actuating arm reaches its open position, thus bringing about a releasable stop of the arm in such a position and, consequently, a safety against unintentional movements of the arm. This makes it possible to mount the actuating unit in any orientation.

An example of a self-retaining group outside the body of the actuating unit is known from document <CIT>. The actuating unit described in <CIT> has a pin constrained to the actuating arm which is dragged by the movement of the actuating arm to fit in an elastic retaining seat when the actuating arm reaches the open position.

In such a solution, the constraint and release coupling between the first and second retaining elements (pin and retaining seat) leads to an unacceptable degree of wear and therefore the need for frequent replacement of parts. Furthermore, the positioning outside the body of the actuating unit leads to an alteration of the overall dimensions generally envisaged for actuating units.

Actuating units are also known which comprise a self-retaining group integrated inside the unit itself, without therefore influencing the overall dimensions of the unit.

A first example, described in document <CIT>, which discloses an actuating unit according to the preamble of claim <NUM>, involves a pair of return valves which prevent air from escaping from the cylinder, thereby maintaining an internal pressure condition even in the absence of a compressed air supply. Such a solution, besides being quite complex from a constructional point of view, may not be particularly effective in maintaining an open condition in the event of a prolonged power failure.

A different solution, described in document <CIT>, comprises a shock absorber and stop group consisting of an axial extension of the closing device fork with an enlarged end intended to be accommodated in an elastic retaining seat when the closing device reaches its opening configuration. In order to allow reversibility from the elastic retaining condition, the shock absorber and stop group described in <CIT> must necessarily be sized so as to be able to ensure that the enlarged end can be released once an axial force is applied to the fork to actuate the closing device. There is therefore no guarantee that the open condition will be reliably maintained. An analogous retaining solution is described in document <CIT>.

Another known solution described in document <CIT> involves an obstacle element to the travel of the fork which is pressed transversely against the fork by an elastic pusher element. Also in this case, the need to dimension the elastic pusher element so as to allow the movement of the fork once an axial force is applied thereto, does not allow a high degree of reliability on the maintenance of the opening condition even in the presence of significant stresses.

Finally, it is known from document <CIT> that a pneumatic cylinder piston locking element is used, comprising a pin held in engagement with the piston by an elastic element. When the pneumatic cylinder is fed, the force exerted by the elastic element is counteracted by the input compressed air. This causes the pin to retract and thus disengage from the piston, allowing the translation thereof. Such a solution, while offering a high degree of reliability, has the disadvantage that a sufficiently high level of pressure must be reached to disengage the pin from the piston. The delay in the release, due to the time needed to reach a level of pressure sufficient to disengage the pin, means that, once free, the piston starts to translate at an already high speed, consequently moving the actuating arm at a speed which may result in a risk of accident for the personnel in charge and/or damage to the object to be handled and/or locked. In fact, during the delay interval the opposite chamber of the piston discharges the pressure, thus not allowing the actuating arm to move in a controlled manner downstream of the release. Analogous retaining solutions are described in documents <CIT> and <CIT>.

Therefore, the Applicant has perceived the need for an actuating unit with an integrated self-retaining group which is not subject to the aforesaid drawbacks.

Document <CIT> discloses a retaining unit comprising a pusher element which acts on a locking element to move it into a position of disengagement from a first retaining element carried by the piston rod.

In view of the foregoing, the problem underlying the present invention is to devise an actuating unit with an integrated self-retaining group which offers a high degree of reliability in maintaining the open condition regardless of the installation orientation of the unit, while ensuring safe operation of the unit.

In the context of such a problem, an object of the present invention is to create an actuating unit with an integrated self-retaining group which is capable of moving the actuating arm in a manner fully comparable to conventional pneumatically operated actuating units, while offering a self-retaining function with a high degree of reliability.

A further object of the present invention is to create an actuating unit with an integrated self-retaining group of low structural complexity and feasible compact size.

In accordance with a first aspect thereof, the invention thus relates to an actuating unit of the articulated lever or cam type comprising an actuator arm rotatable between an open position and a closed operating position; a housing body within which a closing device configured to rotate the actuator arm between the open position and the closed operating position is housed, in which the closing device comprises a mechanism of movement irreversibility configured to engage when the actuator arm reaches the closed operating position; and a fluid-dynamic actuator configured to control the movement of the closing device, the fluid-dynamic actuator comprising a cylindrical body extending between a first head located at a free end of the cylindrical body and a second head for connection to the housing body, and a piston housed in a translatable manner inside the cylindrical body. In particular, the piston carries a first retaining element configured to engage a second retaining element housed in the free end, the second retaining element being movable between an engagement position and a position of disengagement from the first retaining element. According to the invention, a pusher element is also included which is configured to bring the second retaining element into the disengagement position.

In this description and in the appended claims, "cylindrical body" means a body extending along an axis and having the same cross-sectional area along the axis at each point of its extension, the cross-section being of any shape, not necessarily circular.

The Applicant has found that by using a special pusher element acting on the second retaining element to bring it to the disengagement position, it is possible to avoid the release occurring by the direct action of the pressurized fluid on the second retaining element. Thereby, unlocking the piston does not require the generation of high pressure inside the piston chamber, which would result in a dangerous sudden start of the piston.

This avoids dangerous situations and results in a soft piston start, which is similar to actuators without a retaining block.

At the same time, however, the use of a pair of retaining elements which engage with each other to prevent the piston from moving away from the free cylinder head ensures a reliable self-retaining function, even under significant axial stresses.

The pusher element is configured and/or housed in the fluid-dynamic actuator, in particular, in the free head of the fluid-dynamic actuator, so as to be operable by means of a pressurized fluid.

Advantageously, this allows to use the same power source as the actuator, as there is no need for dedicated power supplies to move the pusher element.

The pusher element is housed in the free head so as to intercept a flow between a supply mouth of a pressurized fluid and an inner chamber of the cylindrical body in which the piston is housed.

Such a configuration allows, on the one hand, to reduce the space required to house the pusher element and, on the other, to exploit the pressurized fluid supplied to the actuator through the inlet to move the pusher element.

The pusher element is movable between a rest position in which it obstructs the passage of pressurized fluid to the inner chamber of the cylindrical body and a thrust position in which it frees the passage of pressurized fluid to the inner chamber of the cylindrical body.

Advantageously, as the pusher element can switch between an obstructed position and a position in which it frees the passage of fluid, the supplied fluid is able to act in two distinct steps, first to move the pressurized fluid and then to move the actuator piston.

The present invention can have at least one of the preferred following features; the latter can in particular be combined with one another as desired in order to meet specific application needs.

Preferably, the pusher element is housed in the free head at the pressurized fluid inlet.

More preferably, the free head comprises a pressurized fluid supply pipe connecting the supply mouth to the inner chamber of the cylindrical body, the inlet to the supply pipe being obstructed by the pusher element when it is in the rest position and being cleared by the pusher element when it is in the thrust position.

Such arrangements make it possible to optimize the overall dimensions without substantially altering the overall dimensions of the actuating unit.

In a variant of the invention, the second retaining element is a perforated plate-like element in which the hole is of such a size that the first retaining element is accommodated therein with clearance.

Advantageously, such an embodiment of the second retaining element allows two opposing forces to act thereon, one to push it towards the engaged position and a second, opposing the first, to return it to the disengagement position.

In a variant of the invention, the first retaining element has a tapered conformation in the direction facing the free head to facilitate reaching an engagement configuration with the second retaining element.

In a variant of the invention, an abutting projection is made in the first retaining element configured to engage the second retaining element so as to prevent the translation of the piston away from the free head.

Preferably, the abutting projection is a wall which at least partially delimits a seat obtained in the first retaining element, the seat being configured to accommodate the second retaining element therein when it is in the engaged position thereof.

More preferably, the seat extends along at least a portion of the surface of the first retaining element.

Even more preferably, the seat extends around the first retaining element.

In a variant of the invention, the piston comprises a base sealingly coupled to the inner wall of the body and a control rod extending from the base along an axis of the cylindrical body towards the interface head, in which the first retaining element carried by the piston extends from the base towards the free head.

In a variant of the invention, the first retaining element carries a shock-absorbing cone intended to be housed in a seal housed in the free end.

In a variant of the invention, the second retaining element is housed in the free end translatably in a transverse plane to the axis of the cylindrical body between the engagement position and the disengagement position from the first retaining element.

Preferably, the pusher element is translatable in the translation plane of the second retaining element under the action exerted by the pressurized fluid.

In a variant of the invention, the second retaining element is forced into the engaged position against the abutting projection by an elastic return element.

Preferably, the pusher element exerts a counter force to the elastic force exerted by the elastic return element.

Preferably, the fluid-dynamic actuator is a pneumatic actuator.

Further features and advantages of the present invention will be more evident from the following detailed description of certain preferred embodiments thereof made with reference to the appended drawings.

The different features in the individual configurations may be combined with one another as desired according to the preceding description, should there be advantages specifically resulting from a specific combination.

For the illustration of the drawings, use is made in the following description of identical numerals or symbols to indicate construction elements with the same function. Moreover, for clarity of illustration, certain references may not be repeated in all drawings.

While the invention is susceptible to various modifications and alternative constructions, certain preferred embodiments are shown in the drawings and are described hereinbelow in detail. It is in any case to be noted that there is no intention to limit the invention to the specific embodiment illustrated rather on the contrary, the invention intends covering all the modifications, alternative and equivalent constructions that fall within the scope of the invention as defined in the claims.

The use of "for example", "etc.", "or" indicates non-exclusive alternatives without limitation, unless otherwise indicated. The use of "comprises" and "includes" means "comprises or includes, but not limited to", unless otherwise indicated.

With reference to <FIG>, a preferred embodiment of an actuating unit with articulated lever or cam according to the present invention, indicated as a whole with <NUM>, specifically made in the form of a clamping unit is illustrated.

The clamping unit <NUM> comprises a housing body <NUM> within which a locking device of the articulated lever or cam type (not shown) is arranged, switchable between a first configuration, in which an actuating arm <NUM> is brought into an angular open position, illustrated in <FIG>, and a second configuration, in which the actuating arm <NUM> is brought into an angular closed position, illustrated in <FIG>.

The locking device is actuated by means of a pneumatic actuator <NUM> comprising a cylindrical body <NUM> having a centre-line axis C extending between a pair of heads <NUM>,<NUM> of which a first one <NUM> located at a free end of the cylinder <NUM> and incorporating at least one connection mouth <NUM> to a pressurized fluid supply, and a second one <NUM> acting as a connection interface with the housing body <NUM> of the locking device.

A piston provided with a base <NUM> sealingly coupled to the inner wall of the body <NUM>, a control rod <NUM> extending from the base <NUM> along the axis C towards the interface head <NUM> and a first retaining element <NUM> extending from the base <NUM> towards the free head <NUM> are translatably housed inside the cylindrical body <NUM>.

The first retaining element <NUM> preferably has a tapered shape in the direction towards the free end <NUM>. In addition, a shock-absorbing cone <NUM> intended to be accommodated in a seal <NUM> housed in the free head <NUM> is included on the first retaining element <NUM>.

An abutting projection 27a configured to engage a second retaining element <NUM> is provided in the first retaining element <NUM> so as to prevent the translation of the piston away from the free head <NUM>. The second retaining element <NUM> is housed in the free head <NUM> translatably in a plane transverse to the axis C between a position of engagement with the abutting projection 27a (illustrated in <FIG>) and a position of disengagement from the abutting projection 27a (illustrated in <FIG>).

In the illustrated embodiment, the abutting projection 27a is a wall of a seat made in the first retaining element, within which the second retaining element <NUM> is received when in its engaged position. More in detail, in the illustrated embodiment, the abutting projection 27a is a wall of a receiving seat of a second retaining element <NUM> extending along at least a surface portion of the first retaining element <NUM>, preferably extending around the first retaining element <NUM>.

The second retaining element <NUM> is forced into the engaged position against the abutting projection 27a by an elastic return element <NUM> acting in the translation plane of the second retaining element <NUM>.

According to the present invention, the second retaining element <NUM> is further acted upon, in opposition to the elastic return element <NUM>, by a release pusher <NUM> housed at a supply mouth <NUM> of a pressurized fluid.

In particular, the release pusher <NUM> is housed in the supply mouth <NUM> so as to be translatable in the translation plane of the second retaining element <NUM> under the action exerted by the pressurized fluid, exerting on the second retaining element <NUM> a force counteracting the elastic force exerted by the elastic return element <NUM>. Thereby, the second retaining element <NUM> can be pushed by the release pusher <NUM> into the disengagement position from the projection 27a (illustrated in <FIG>).

In the illustrated embodiment, the release pusher <NUM> is advantageously housed in the supply mouth <NUM> so that it is free to translate between a rest position in which the pusher <NUM> is more distanced from the elastic return element <NUM>, allowing the latter to keep the second retaining element <NUM> in the engaged position, and a compression position, in which the pusher <NUM> pushes the second retaining element <NUM> to approach the elastic return element <NUM> by the compression of the latter.

In particular, in the spaced position (illustrated in <FIG> and <FIG>), the pusher <NUM> obstructs a supply pipe <NUM> of the pressurized fluid to the piston <NUM>,<NUM>,<NUM>, while in the compression position (illustrated in <FIG>), the pusher <NUM> does not obstruct the supply pipe <NUM>, allowing the pressurized fluid to reach the piston.

In the embodiment illustrated, the second retaining element <NUM> is advantageously obtained in the form of a perforated plate in which the hole has a sufficient diameter to accommodate the first retaining element <NUM> with clearance. In alternative embodiments, however, the second retaining element <NUM> can assume different conformations, for example by having a housing for the first retaining element <NUM> which is not necessarily closed.

The operation of the articulated lever or cam actuating unit <NUM> according to the present invention is as follows.

In the open condition, illustrated in <FIG>, the piston is fully retracted with the shock-absorbing cone <NUM> fully inserted in the seal <NUM> in the free end <NUM>.

In this condition, the pneumatic actuator <NUM> is not energized and therefore the release pusher <NUM> is not forced by the pressurized fluid to counteract the force exerted by the elastic return element <NUM>, thus being in the position distanced from said element <NUM>. This allows the elastic return element <NUM> to force the second retaining element <NUM> into the engaged position against the abutting projection 27a.

In this configuration, the piston is locked in its position against the free end <NUM>, ensuring that it maintains such a position even when subjected to axial stress. This ensures that the actuating arm <NUM> is reliably maintained in its open position (illustrated in <FIG>).

The movement of the piston and thus operation of the locking device is only possible after the piston has been released. Such a release is achieved by the action of the pressurized fluid fed to the pneumatic actuator.

The pressurized fluid initially acts on the release pusher <NUM> because, in the initial configuration, the supply pipe <NUM> of the pressurized fluid to the piston <NUM>,<NUM>,<NUM> is obstructed by the pusher <NUM> itself. In particular, the pressurized fluid exerts a thrust force sufficient to counteract the force exerted by the elastic return element <NUM>, allowing the release pusher <NUM> and the second retaining element <NUM> to translate.

In fact, the release pusher <NUM> acts on the second retaining element <NUM>, overcoming the force exerted by the elastic return element <NUM> and pushing the second retaining element <NUM> towards its disengagement position from the projection 27a (illustrated in <FIG>). Thereby the piston is free to move.

The movement of the release pusher <NUM> also causes the opening of the supply pipe <NUM> and thus a gradual increase in the pressure exerted on the piston until it moves.

In the absence of a pressurized fluid supply, the release pusher <NUM> returns to its distanced position from the spring return element <NUM>, allowing said spring return element <NUM> to push the second retaining element <NUM> towards the engagement position (see <FIG>).

Claim 1:
Actuating unit (<NUM>) of the articulated lever or cam type comprising
- an actuator arm (<NUM>) rotatable between an open position and a closed operating position;
- a housing body (<NUM>) inside of which a closing device configured to bring the actuator arm (<NUM>) into rotation between the open position and the closed operating position is housed, wherein the closing device comprises a mechanism of movement irreversibility configured to trigger when the actuator arm (<NUM>) reaches the closed operating position; and
- a fluid-dynamic actuator (<NUM>) configured to control the movement of the closing device, the fluid-dynamic actuator (<NUM>) comprising a cylindrical body (<NUM>) which extends between a first free head (<NUM>) located at a free end of the cylindrical body (<NUM>) and a second head (<NUM>) for connection with the housing body (<NUM>); and a piston housed in a translatable manner inside the cylindrical body (<NUM>),
wherein the piston carries a first retaining element (<NUM>) configured to engage a second retaining element (<NUM>) housed inside the free head (<NUM>), the second retaining element (<NUM>) being movable between an engagement position and a position of disengagement from the first retaining element (<NUM>),
characterized in that it comprises a pusher element (<NUM>) configured to bring the second retaining element (<NUM>) into the position of disengagement from the first retaining element (<NUM>), wherein the pusher element (<NUM>) is configured and/or housed in the fluid-dynamic actuator (<NUM>) such that it is operable by means of a pressurized fluid, and is housed in the free head (<NUM>) so as to intercept a fluid flow between a pressurized fluid supply mouth (<NUM>) and an inner chamber of the cylindrical body (<NUM>) in which the piston is housed, wherein the pusher element (<NUM>) is movable between a rest position in which it obstructs the passage of pressurized fluid to the inner chamber of the cylindrical body (<NUM>) and a thrust position in which it frees the passage of pressurized fluid to the inner chamber of the cylindrical body (<NUM>).