A MODULAR CONTROL APPARATUS FOR ACTUATING HYDRAULIC VALVE SYSTEMS

Abstract

A modular control apparatus for actuating hydraulic valve systems includes an actuating section including a tilting control member and a plurality of control rods provided with a pusher, which interacts with the control member so as to translate the control rods in the longitudinal direction, a sensor section including a plurality of sensor members suitable to detect a movement in the longitudinal direction of said control rods and a blocking section comprising a blocking device that is capable of individually blocking in the longitudinal direction each of said control rods. The actuating section can be alternately connected to the blocking section or to the sensor section so that the sensor section can be directly connected to the actuating section, detecting the longitudinal movement of the control rods also if the blocking section is not present.

Claims

1. A modular control apparatus (100) for actuating hydraulic valve systems comprising: an actuating section (1) including a tilting control member (10) about a hinging point (O) and a plurality of control rods (11) arranged about the hinging point (O) and provided with a pusher (12) configured to interact with the control member (10) as a result of an oscillation thereof about the hinging point (O) so as to translate the control rods in a longitudinal direction (X); a sensor section (3) including a plurality of sensor members (30) for detecting a movement in the longitudinal direction of said control rods (11); an auxiliary section (2) comprising a blocking device (20), capable of individually blocking in the longitudinal direction (X) each of said control rods (11), or a haptic device (20′), capable of providing the user of the control apparatus (100) with a feedback as a function of the displacement of the tilting control member (10), said auxiliary section (2) comprising a first and a second connecting interfaces (41, 42) through which said auxiliary section (2) can be connected to the actuating section (1) and the sensor section (3), respectively; wherein said actuating section (1) comprises a third connecting interface (43) through which said actuating section (1) can be alternately connected to the auxiliary section (2) or to the sensor section (3) so that the sensor section (3) can be directly connected to the actuating section (1), detecting the longitudinal movement of the control rods (11) also if the auxiliary section (2) is not present; wherein the actuating section (1), the auxiliary section (2) and the sensor section (3) comprise a respective casing (1A, 2A, 3A).

2. The modular control apparatus (100) according to claim 1, wherein said first connecting interface (41), second connecting interface (42) and third connecting interface (43) are configured in such a way as to achieve a mechanical coupling between the actuating section (1), the auxiliary section (2) and the sensor section (3).

3. The modular control apparatus (100) according to claim 1, wherein the actuating section (1), the auxiliary section (2) and the sensor section (3) are formed as separate units, so that the auxiliary section (2) can be physically removed from the control apparatus, or not inserted in an assembly phase of the same.

4. The modular control apparatus (100) according to claim 1, wherein said second connecting interface (42) is identical to said third connecting interface (43).

5. The modular control apparatus (100) according to claim 1, wherein the auxiliary section (2) comprises auxiliary rods (21) that are integral to or that can be made integral to the control rods (11) in said longitudinal direction, said auxiliary rods (21) comprising ends (21A) that are detectable by the sensor members (30).

6. The modular control apparatus (100) according to claim 5, wherein the auxiliary section (2) comprises recesses (22) in which the control rods (11) can be received, said blocking device (20) being located at the recesses (22) and configured so as to hold on command the control rods (11) and/or the auxiliary rods (21) in the longitudinal direction.

7. The modular control apparatus (100) according to claim 1, wherein the blocking device (20) comprises at least one electromagnet (23).

8. The modular control apparatus (100) according to claim 7, wherein the blocking device (20) is configured so as to generate a magnetic attraction that is suitable to attract the control rod (11) towards an extraction direction.

9. The modular control apparatus (100) according to claim 5, wherein said control rods (11) and/or said auxiliary rods (21) comprise a hooking member (13) configured so as to couple the control rod to one of the auxiliary rods, thus making them integral in the longitudinal direction (X).

10. The modular control apparatus (100) according to claim 1, wherein said control rods (11) project from said actuating section (1) and are shaped so as to be insertable into respective holes (31), which are defined in said sensor section (3), within which the sensor members (30) act to detect the movement in the longitudinal direction of the control rods (11) when the blocking section (2) is not present.

11. The modular control apparatus (100) according to claim 5, wherein said control rods (11) project from said actuating section (1) and are shaped so as to be insertable into respective holes (31), which are defined in said sensor section (3), within which the sensor members (30) act to detect the movement in the longitudinal direction of the control rods (11) when the blocking section (2) is not present; and wherein said auxiliary rods (21) project from said auxiliary section (2) and are shaped so as to be insertable into the holes (31) defined in said sensor section (3).

12. The modular control apparatus (100) according to claim 1, wherein the connecting interfaces (41, 42, 43) comprising a shaped portion.

13. The modular control apparatus (100) according to claim 12, wherein said casings (1A, 2A, 3A) are configured so as to define a shaped portion.

14. The modular control apparatus (100) according to claim 1, wherein said rods (11) are arranged in pairs that are diametrically opposite with respect to the hinging point (O), said pushers (12) being coupled to said control member (10) so that a displacement in the longitudinal direction (X) in a first direction of a rod causes a corresponding displacement of a diametrically opposite rod in an opposite direction of said longitudinal direction (X).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0035] The features and the advantages of the invention will become clearer from the detailed following description of some of its preferred embodiment examples illustrated, by way of non-limiting example, with reference to the accompanying drawings in which:

[0036] FIG. 1 is a perspective view of a control apparatus according to the present invention with a lever inclined laterally;

[0037] FIG. 1A is a perspective view from the control apparatus of FIG. 1 from which a lever and a cover sleeve have been removed for greater expository clarity;

[0038] FIGS. 2 and 2A are a lateral section view and a relative detail of the control apparatus of FIG. 1 in the rest position, with some components omitted for illustrative clarity;

[0039] FIGS. 3A and 3B are a section lateral view and a section perspective view of the control apparatus of FIG. 1 with the lever in the rest position and in the inclined position, respectively;

[0040] FIGS. 4A, 4B and 4C are perspective views, of which FIG. 4C is a section view, of respective actuating, blocking and sensor sections, which represent details of the apparatus according to the present invention; and

[0041] FIG. 5 is a schematic illustration, according to a perspective view, which illustrates different ways of combining the sections represented in FIGS. 4A, 4B and 4C.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0042] With reference initially to FIG. 1, 100 indicates overall a control apparatus according to the present invention.

[0043] Preferably, the control apparatus according to the present invention finds preferred application in the realisation of joysticks of the heavy-duty type, therefore of the type typically intended for actuations in operating machines.

[0044] As schematically illustrated in FIG. 5, the control apparatus 100 is essentially formed by several sections, which, in a preferred embodiment, can be assembled and stacked together in a pack-like configuration.

[0045] With reference now also to FIG. 2, the apparatus 100 comprises an actuating section 1 including a tilting control member 10 about a hinging point O.

[0046] Preferably, the control member 10 is supported by means of a joint of the universal type, that is a joint formed by two perpendicular hinging axes, which therefore allows the oscillation movement about a point described above.

[0047] In a preferred embodiment, on the control member 10, for example made in the form of a rigid cap, the characteristics of which will be better illustrated below, a lever 5 is connected, shaped in such a way that it can be grasped by a user. In this way the lever 5 can be easily moved in order to tilt the control member 10 into the required position.

[0048] The actuating section 1 further comprises a plurality of control rods 11 arranged about the hinging point O. Preferably, the rods 11 are provided with a pusher 12 susceptible to interaction with the control member 10 so as to translate the control rods in the longitudinal direction X.

[0049] In some embodiments, the control member 10 comprises coupling members 10A which allow the rods 11 to be constrained to the control member 10, making them translate in the longitudinal direction X following the oscillation of the control member 10 itself.

[0050] The connection between the control member 10 and the pushers 12 is illustrated in an exemplary version in FIGS. 2 and 2A.

[0051] With reference to these figures, according to a preferred embodiment, the pushers 12 comprise heads 12B, which form an enlargement with respect to the rod portion 12C on which they are mounted.

[0052] The heads 12B are housed in respective seats, forming the coupling member 10A, through which the portion 12C can pass but not the head 12B as a whole. In this way a coupling can be achieved between the head 12B and a respective abutment surface 10B formed on the control member 10.

[0053] According to other aspects, the control member 10 can further comprise a blocking body 10C. Preferably, the blocking body 10C can couple with a base portion of the control member 10, for example by snap-fitting, so as to close the heads 12B in a pack-like configuration between the abutment surface 10B and the blocking body 10C.

[0054] In this way, the pushers 12, and consequently the rods 11, can follow the movement of the control member 10 in both directions along the longitudinal direction X in two opposite directions, therefore both in extraction and insertion with respect to the actuating section 1.

[0055] More generally, a bidirectional constraint between rods 11 and control member 10 can be provided so as to obtain a redundancy in the signal generated following the movement of the rods 11, as will be better illustrated below.

[0056] It will however be appreciated that in some embodiments, the actuating section 1 can comprise an elastic member 14 which stresses the rod 11.

[0057] In this case, and in general as an alternative to the embodiment shown in the figures, the iteration between the pusher 12 of the rods 11 and the control member 10 can take place by simple contact, following the contact with an abutment surface of control member 10. In some of these variants, the coupling member 10A can be omitted, thanks to the presence of the elastic member.

[0058] Preferably, in order to maintain the redundancy characteristic in the signal generated by the rod, it can be provided that the elastic member holds the pusher in contact with the control member also during the extraction phase of the rod 11.

[0059] More generally, redundancy can be obtained, in various embodiments, by providing that the pushers 12 are coupled to the control member 10 in such a way that a displacement in a first direction of a rod 11 causes a corresponding displacement of the diametrically opposite rod with respect to the hinging point O in the opposite direction along the longitudinal direction X.

[0060] With reference now to FIG. 4A, the control rods 11 comprise a respective end section 11A projecting from the actuating section 1. In one embodiment, the end 11A, or more generally the rod, is shaped so as to be insertable into a respective hole 31 defined in a sensor section 3.

[0061] Inside the sensor section 3 there are sensor members 30 capable of detecting the movement in the longitudinal direction of the control rods 11. By way of example, these sensors 30 may be of the Hall effect type but it will be understood that sensors of other type, both of the mechanical and electromechanical type, may also be provided.

[0062] The movement detected by the sensor members 30 is then transmitted to the hydraulic system, in a manner known per se, to suitably control the desired valve actuations.

[0063] The apparatus according to the present invention can also optionally comprise an auxiliary section 2 capable of providing additional and, precisely, auxiliary functions to the control apparatus.

[0064] Preferably, the auxiliary section 2 is configured to individually block in the longitudinal direction X each of said control rods 11, by means of a suitable blocking device 20 which will be illustrated in greater detail below.

[0065] A further embodiment of the auxiliary section 2 is also represented by a haptic system, in which a haptic device 20′ is used, the latter illustrated schematically, only for conceptual purposes, in FIG. 4. The haptic device 20′ may be capable of providing the user of the control apparatus with a feedback as a function of the displacement of the tilting control member, for example by imparting a force capable of opposing a further displacement of the control member, or by requiring more force for the displacement thereof in the presence of predetermined conditions. It is however evident that different types of auxiliary sections may also be provided, for example that combine the blocking function with the haptic one.

[0066] Below, reference will be made to an embodiment in which the auxiliary section 2 has a blocking function and, for this reason, it will also be referred to as the blocking section 2, in any case it being understood that the present invention also finds application in the case of a haptic section.

[0067] The blocking device, or the haptic device, is optional in the sense that it may or may not be included in the apparatus of the present invention based on specific needs. In other words, the auxiliary section 2 is configured as an autonomous section, which can be inserted between the actuating section 1 and the sensor section 3 as a function of specific needs.

[0068] This is achieved through a suitable connection system between the sections which enables making the actuating section 1, the auxiliary section 2 and the sensor section 3 separate units, so that the auxiliary section 2 can be physically removed from the control apparatus, or not inserted in an assembly phase of the same.

[0069] As in fact illustrated in FIG. 3 and clarified in FIG. 5, the auxiliary section 2 comprises a first connecting interface 41 and a second connecting interface 42 through which it can be connected to the actuating section 1 and to the sensor section 3, respectively.

[0070] In turn, the actuating section 1 comprises a third connecting interface 43 through which it can be alternately connected to the auxiliary section 2 or to the sensor section 3.

[0071] On the basis of a further aspect of the invention, the sensor section will in turn comprise a connecting interface 44 alternately connectable to the second or third interface, that is, to the actuating section or to the auxiliary section.

[0072] In light of the configuration described above, it is evident that the sensor section 3 can be directly connected to the actuating section 1, detecting the longitudinal movement of the control rods 11 also in the case that the auxiliary section 2 is not present.

[0073] This allows in fact obtainment of two different variants of the control apparatus of the present invention, without the need to radically modify the components used, thus making the apparatus modular.

[0074] In some embodiments, the second connecting interface 42 is identical to the third connecting interface 43.

[0075] Preferably, the actuating section 1, auxiliary section 2 and sensor section 3 comprise a respective casing 1A, 2A, 3A, as illustrated in FIG. 3B.

[0076] In some embodiments, the connecting interfaces 41, 42, 43 may comprise a shaped portion of the casing.

[0077] The shaped portion can be defined by a shaped edge 2B of the casing of the casings, engageable in a counter-shaped slot 3B, as for example can be seen in FIG. 3B, at the connecting interface between the auxiliary section 2 and the sensor section 3. It is however evident that different embodiments of the shaped portion may also be provided, which may be formed by holes or seats in which to engage screws or pins or simply by a specific arrangement of the casing in order to allow the assembly between the different sections, also by using additional connecting members.

[0078] In one embodiment, the auxiliary section 2 comprises auxiliary rods 21 which can be connected to the control rods 11 in such a way as to make them integral along the aforesaid longitudinal direction X. For this purpose, the actuating section 1 and/or the auxiliary section 2 can have a special hooking member 13.

[0079] By way of example, the hooking member 13 can be formed by a groove and a corresponding ring, made respectively on the former and the latter of the control rods 11 and of the auxiliary rods 21 for mutual engagement.

[0080] According to a preferred embodiment, to make the connection between the rods 11 and 21 more precise, at one end of the former there is a cavity which is suitable for holding the end of the latter. Preferably, the groove and the ring are made at the cavity and at the end or vice versa.

[0081] In one embodiment, also the auxiliary rods 21 comprise ends 21A, preferably also provided with a further magnetic member, suitable for being detected by the sensor members 30, by inserting them into the same holes 31 used for the control rods 11. In other words, if the auxiliary section 2 is present, the ends 21A are inserted into the holes 31 for detecting their position whereas, if this is not used, the ends 11A of the control rods 11 will be inserted into the holes 31.

[0082] With reference now also to FIG. 4B, according to a preferred embodiment, the auxiliary section 2 comprises recesses 22 in which the control rods 11 can be received.

[0083] With reference now again to FIGS. 2 and 3A, B an example of embodiment of the blocking device 20 will be described.

[0084] As can be seen from FIGS. 3A, B, the blocking device 20 is preferably located at the recesses 22 and configured so as to hold on command the control rods 11 and/or the auxiliary rods 21 in the longitudinal direction.

[0085] In some embodiments, the blocking device 20 comprises at least one electromagnet 23 and preferably comprises a plurality of electromagnets 23, each extending about one of said recesses 22.

[0086] The electromagnet can therefore act on the control rod 11 blocking the translation thereof in the longitudinal direction. In one embodiment this takes place by using a plate 24 fixed to the auxiliary rods 21. The plate 24 can be subject to attraction by the electromagnet 23, thus preventing displacements of the rod, and therefore of the control member, until the action of the electromagnet is interrupted or until a sufficient stress is imparted to the lever. This advantageously allows both to be able to unblock the system manually, by operating with sufficient force, and automatically, in the event of an emergency situation.

[0087] It will also be appreciated that the electromagnet is configured in such a way that, in use, this is arranged above the plate 24, as can be seen from the example of FIG. 3B. More generally, the blocking device 20 is configured so as to generate a magnetic attraction suitable for attracting the respective control rod 11 towards the extraction direction.

[0088] Consequently, in light of the redundancy in the movements of the rods 11 provided in the apparatus of the present invention, the blocking of the rod, which performs the extraction movement, takes place. In this regard, as highlighted above, following the movement of the lever 5 in one direction, the simultaneous movement of two diametrically opposite rods takes place, one in the longitudinal direction in the insertion direction and the other one in the opposite extraction direction. Thanks to the configuration described above, the blocking action takes place on the rod moved in the extraction direction, with the other rod being, on the contrary, moved away from the magnetic member 23.

[0089] This allows the electromagnet to be held in a remote position with respect to the sensor members 30, thus preventing them from being disturbed by the presence of the electromagnet 23.

[0090] It is however evident that blocking devices of a different type, for example mechanical ones, can also be used. For this purpose, a seat can be provided in the control rod, which can be engaged in a respective abutment member.

[0091] By providing that the abutment member is stressed towards the rod but that it can be moved away therefrom if sufficient force is acting, it is possible to obtain a solution similar to that described above with reference to the use of an electromagnetic blocking device.

[0092] The invention therefore solves the proposed problem, while at the same time achieving a plurality of advantages, including the possibility of obtaining a modular control apparatus capable of operating with the same mechanical and electronic components both in case it is necessary to include a blocking function or the haptic function, and in the case that this is not required.

[0093] Even the overall structure of the apparatus can easily adapt to the different configurations since the connecting interfaces make the sections easily interchangeable with each other.