Patent Application
20200002903
This application claims benefit of Ser. No. 102018000006830, filed 29 Jun. 2018 in Italy and which application is incorporated herein by reference. To the extent appropriate, a claim of priority is made to the above disclosed application.
The present invention concerns an excavation apparatus for an operating machine, and an operating machine comprising such apparatus.
The use of excavation devices that may be connected to excavators for the construction of trenches, or for the removal of layers of asphalt or the like, is well known.
A problem felt in this sector is the functional reliability over time, as the drums or the excavation wheels of the apparatuses are traditionally subjected to enormous stresses (in particular of the flexural type), which could compromise their operation in an exaggeratedly short life cycle.
The present invention is part of the preceding context, proposing to provide an excavation apparatus and an operating machine capable of overcoming the drawbacks reported.
In particular, this apparatus is of high strength and allows the excavation forces to be discharged in a balanced way on the mechanical components in order to reduce the effects of wear.
The object of the present invention will now be described in detail, with the aid of the figures, provided by way of illustrative and non-limiting example, wherein:
With reference to the aforesaid figures, the reference number 1 indicates, in its totality, an apparatus for an operating machine.
According to one embodiment, this apparatus is an excavation apparatus.
According to one embodiment, this apparatus is a milling apparatus.
This excavation apparatus 1 comprises an apparatus body 2, a rotating excavation tool 8 and a self-leveling body 10.
According to one embodiment, the excavation tool 8 is in the form of a wheel or disc.
According to one embodiment, the excavation tool 8 is in the form of a roller or cylinder.
According to one embodiment, the excavation tool 8 comprises peripherally a plurality of excavation elements 54, for example oriented in a tangential direction with respect to a rotation axis R of such tool.
It should be noted that, unless otherwise specified, the terms “axial”, “radial” or “tangential” shall always refer to the rotation axis R.
The apparatus body 2 comprises a portion 4 for coupling to the operating machine and delimits a first body compartment 6 wherein an excavation tool 8 of the apparatus 1 is partly housed.
According to one embodiment, in a plane orthogonal to the rotation axis R, the first body compartment 6 has a circular sector cross-section.
According to one embodiment, the coupling portion 4 comprises an attachment plate 56 penetrated by a plurality of attachment holes 58 for locking the apparatus 1 to the operating machine, for example to a movable arm or to a support of the latter.
The self-leveling body 10 comprises a pair of abutment runners 12, 14 with a working surface Z.
In the embodiment shown, the position of the abutment runners 12, 14 with respect to the excavation tool 8 is adjustable in a mutually dependent manner, so that the distance of these runners with respect to the excavation surface may be the same for both runners. For example, this adjustment could be achieved using a single depth adjustment device 24.
According to one embodiment, the position of the abutment runners 12, 14 with respect to the excavation tool 8 is adjustable independently, whereby the distance of each abutment runner with respect to the excavation surface may be selected independently. For example, such an adjustment could be achieved by means of a pair of adjustment devices 24, advantageously acting in parallel with each other.
According to this variant, the apparatus 1 could advantageously comprise a device 24 for adjusting the excavation depth X—as described below—for each abutment runner 12, 14.
It follows that this variant advantageously provides that the transverse walls 16, 18 may be separated from each other, so that each of these may assume a different position with respect to the apparatus body 2, for example, each through its own adjustment device 24, and thus so that one abutment runner 12, 14 is adjustable separately from the other abutment runner.
According to this variant, the apparatus 1 could advantageously be devoid of longitudinal walls 20, 22 connecting the transverse walls.
The self-leveling body 10 is rotatably mounted in an idle manner with respect to the apparatus body 2, so that the coupling portion 4 may assume different angular positions with reference to a rotation axis substantially parallel or coincident to the axis R—with respect to the abutment runners 12, 14.
Such freedom of movement is well exemplified in
It follows that the excavation apparatus 11 is designed so that the abutment runners 12, 14 always remain in contact with the working surface Z, regardless of the angular position of the coupling portion 4 (and of the arm or support of the operating machine connected thereto), specifically so that the excavation depth X remains constant or unchanged for a given excavation operation of the excavation tool 8.
According to one embodiment, the self-leveling body 10 and the apparatus body 2 may thus be rotated parallel to the rotation axis R.
According to one embodiment, the self-leveling body 10 guided by the apparatus body 2 into the different angular positions by guide means cooperating between these bodies 10, 2.
According to one embodiment, the guide means comprise at least one edge of a guide slot 64 slidably engaged by at least one guide pin 66.
According to one embodiment, the self-leveling body 10 comprises at least one pair of transverse walls 16, 18 axially offset along the rotation axis R, rigidly connected by means of a pair of longitudinal walls 20, 22 of this body 10 for delimiting a box-shaped structure housing the excavation tool 8 in a manner protruding frontally to the abutment runners 12, 14.
According to one embodiment, the self-leveling body 10 comprises at least one pair of transverse walls 16, 18 (or comprises only these walls) axially offset along the rotation axis R, connected to the apparatus 2 in a sliding manner. In this variant, the pair of transverse walls 16, 18 axially houses the excavation tool 8 protruding frontally to the abutment runners 12, 14.
In this way, this excavation tool 8 is able to remove or excavate a solid material from the working surface Z, for example vertically downwards according to the orientation of
This device 1 may therefore be moved in one working direction W by virtue of the sliding contact between the abutment runners 12, 14 and the working surface Z.
According to one embodiment, the abutment runners 12, 14 are arranged next to the excavation tool 8.
According to one embodiment, the abutment runners 12, 14 are made from folded metal sheets.
According to one embodiment, the abutment runners 12, are made in one piece with a respective transverse wall 16, 18.
According to one embodiment, one or more transverse walls 16, 18 and/or one or more longitudinal walls 20, 22 are substantially planar.
According to one embodiment, the transverse walls 16, and the longitudinal walls 20, 22 are connected at right angles.
According to one embodiment, the transverse walls 16, 18 and the longitudinal walls 20, 22 delimit a second body compartment 60.
According to one embodiment, the apparatus body 2 is at least partly housed between the transverse walls 16, 18 and the longitudinal walls 20, 22, in particular in the second body compartment 60.
According to one embodiment, at least one longitudinal wall 20, 22 comprises structural stiffening means made in one piece with this wall 20, 22.
According to one embodiment, the stiffening means are in the form of a folded portion 24 (in particular in the radial direction) of a sheet forming at least part of that wall.
According to one embodiment, the second body compartment 60 has a substantially square or rectangular cross-section parallel to the working surface Z.
According to one embodiment, the transverse walls 16, and the longitudinal walls 20, 22 are fastened together in a monolithic manner, for example welded or joined by mechanical locking means.
According to one embodiment, the transverse walls 16, and the longitudinal walls 20, 22 are joined by welding.
According to one embodiment, the transverse walls 16, 18 and the longitudinal walls 20, 22 are joined together by mechanical locking means, for example, threaded.
According to one embodiment, one or both longitudinal walls 20, 22 may protrude axially with respect to the transverse walls 16, 18.
According to one embodiment, at least one transverse wall 16, 18 (for example both) could include at least one axial protrusion 62 (for example an opposite pair of such protrusions 62) to couple to one or both transverse walls 16, 18.
According to one embodiment, the mechanical means between the transverse walls 16, 18 and the longitudinal walls 20, 22 could be engaged at one or more axial protrusions 62.
According to one embodiment, the apparatus body 2 is mechanically connected to the self-leveling body 10 so as to weigh in a balanced manner on the transverse walls 16, 18 and on the abutment runners 12, 14.
According to one embodiment, the apparatus body 2 is connected to the self-leveling body 10 by at least one device 24 for adjusting the excavation depth X of the apparatus 1.
The function of the adjustment device 24 according to this variant is thus to modify or adjust the projection of the excavation tool 8 with respect to the abutment runners 12, 14, and thus the adjustment of the excavation depth.
It should be noted that the adjustment device 24 is operated (for example by the wrench or adjusting tool U, or pneumatically, hydraulically or mechanically) in order to determine the excavation depth X.
However, after the desired excavation depth has been established (i.e. after the least or greatest projection of the excavation tool 8 frontally with respect to the abutment runners 12, 14 has been determined), this device provides for keeping this adjustment or setting constant or unchanged throughout the given excavation operation.
According to one embodiment, the adjustment device 24 comprises adjustment elements 26, 28 acting symmetrically on the transverse walls 16, 18.
According to one embodiment, the adjustment elements 26, 28 comprise one or more first radial levers 68.
According to one embodiment, the adjustment elements 26, 28 are connected to one or more movable adjustment shafts 30 for both of these elements 26, 28 synchronously.
According to one embodiment, a single adjustment shaft is provided to which are associated or joined the adjustment elements 26, 28.
According to one embodiment, a pair of first radial levers 68 may be associated or joined to the axial ends of the adjustment shaft 30, in particular in a manner rotationally integral to this shaft.
According to one embodiment, at least one guide pin 66 may be fastened to one free end of a first radial lever 68.
According to one embodiment, the transverse walls 16, 18 and the apparatus body 2 comprise guide means 36 of the excavation tool 8 in different adjustment positions of the excavation depth X thereof.
The adjustment positions are arranged along an adjustment direction D as shown by the double arrow in
According to one embodiment, the guide means 36 comprising a pair of lateral guides 38, 40 associated with the transverse walls 16, 18 (or with the apparatus body) that delimit between them a sliding space 42, and a sliding member 44 associated with the apparatus body 2 (or with the transverse walls) housed at least in part in the sliding space 42 in a sliding manner.
According to one embodiment, the sliding member 44 is connected to the apparatus body 2.
According to one embodiment, the sliding member 44 is substantially annular in shape.
According to one embodiment, an outer annular surface 46 of the sliding member 44 is in abutment with the lateral guides.
According to one embodiment, an inner annular surface 48 of the sliding member 44 forms a rotational guide for the excavation tool 8.
According to one embodiment, the adjustment device 24 comprises a first actuator 50 (for example linear or rotational) acting in thrust or in traction between the apparatus body 2 and the self-leveling body 10, specifically in a tangential direction S with respect to a circumference centered on the rotation axis R.
According to one embodiment, the first actuator 50 is fixed at a first portion 70 to the apparatus body 2 and is fixed at a second portion 72 to the self-leveling body 10, advantageously in an articulated way at these portions 70, 72.
According to one embodiment, the first actuator 50 is mechanically connected to one or more adjustment shafts 30, for example by means of a second radial lever 74.
According to one embodiment, the second radial lever 74 is integral in rotation to one or more adjustment shafts 30 and is hinged to the first actuator 50 at one of its radial ends.
Thus, as a result of a force exerted by the actuator 50—for example, as a result of approaching or moving away from the opposite ends thereof—this actuator 50 will rotate the radial lever 74 in a direction that causes a raising or lowering of the self-leveling body 10 with respect to the apparatus body 2 (by virtue of the sliding of the guide pin 66 along the slot 64), and thus a corresponding movement of the excavation tool 8.
This adjustment device 24 has been discussed by way of example only. Other ways of adjusting the excavation depth according to other embodiments are possible.
According to one embodiment, the excavation tool 8 may be rotated with respect to the apparatus body 2 by motor means 52.
According to one embodiment, the motor means 52 are of the hydraulic type.
According to one embodiment, the motor means 52 are engaged with and are movable integrally with the excavation tool 8 in the different adjustment positions of the excavation depth X.
The aforesaid objectives are also achieved by means of an excavation assembly comprising an operating machine and an excavation apparatus 1, according to any of the embodiments illustrated above, fixed to a movable arm or support of the operating machine.
According to one embodiment, the operating machine 10 could comprise a fluidic power take-off to power the hydraulic type motor means 40.
Innovatively, the apparatus and the assembly object of the present invention are suitable to overcome successfully the drawbacks discussed previously.
More precisely, the apparatus described makes it possible to guarantee a greater solidity over time with respect to traditional apparatuses.
Advantageously, the apparatus and the assembly object of the present invention allow the flexural forces acting on the body that compose it to be reduced or eliminated.
Advantageously, the apparatus object of the present invention may be operated with fewer levers or controls with respect to traditional apparatuses.
Advantageously, the apparatus object of the present invention is constructed in a rational manner.
To the embodiments of the aforesaid apparatus and operating machine, one skilled in the art, in order to meet specific needs, may make variants or substitutions of elements with other functionally equivalent ones.
Also these variants are contained within the scope of protection as defined by the following claims.
Moreover, each variant described as belonging to a possible embodiment may be implemented independently of the other variants described.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102018000006830 | Jun 2018 | IT | national |
