Tracked undercarriage for operating machines

Abstract

A tracked undercarriage for oscillating and retractable operating machines includes a main frame, a track unit mounted on each of two opposite sides of the main frame, and a sliding frame mounted on each of the two opposite sides of the main frame, Each sliding frame has the dual function of translating the corresponding track unit with respect to the main frame and to vary the inclination of the track unit with respect to the main frame.

Claims

1. A tracked undercarriage (100) for operating machines comprising: a main frame (110) defining a first longitudinal direction (X); a track unit (120, 130) mounted on each of two opposite sides (112, 113) of said main frame (110) and arranged parallel to said first longitudinal direction (X), each track unit (120, 130) comprising a structure (121, 131) and at least one track (122, 132) mounted on said structure (121, 131); and a sliding frame (200, 300) mounted on each of said two opposite sides (112, 113) of said main frame (110), wherein said sliding frame (200, 300) comprises: a longitudinal member (210, 310) arranged parallel to said first longitudinal direction (X) and interposed between said main frame (110) and a corresponding track unit (120, 130); first constraining means, for slidingly constraining said longitudinal member (210, 310) to said main frame (110), said first constraining means being configured to enable said longitudinal member (210, 310) to translate with respect to said main frame (110) in a second translation direction (Y), orthogonal to said longitudinal direction (X); second constraining means, for rotatably securing the structure (121, 131) of the corresponding track unit (120, 130) to a corresponding longitudinal member (210, 310), said second constraining means being configured to enable said track unit (120, 130) to rotate with respect to said longitudinal member (210, 310) around an axis of rotation (Y1), orthogonal to said longitudinal direction (X); translation means (230, 240, 330, 340, 400), configured to cause a sliding of said longitudinal member (210, 310) with respect to said main frame (110) in said second translation direction (Y); and rotation means (500), configured to cause a rotation of said track unit (120, 130) with respect to said longitudinal member (210, 310) around said rotation axis (Y1).

2. The tracked undercarriage (100) according to claim 1, wherein said first constraining means of each sliding frame (200, 300) comprise at least one beam (230, 240, 330, 340) placed parallel to said second translation direction (Y) and slidably housed in a guide or seat (140, 150) made in said main frame (110).

3. The tracked undercarriage (100) according to claim 2, wherein said at least one beam (330, 340) of the sliding frame (300) on one side slides inside a cavity (250) made in the at least one beam (230, 240) of the sliding frame (200) of an opposite side, such that the two sliding frames (200, 300) mounted on said two opposite sides together make up a telescopic structure, and can slide relative to each other between a contracted position and an extended position.

4. The tracked undercarriage (100) according to claim 2, wherein said first constraining means of each sliding frame (200, 300) comprise at least two of said beams (230, 240, 330, 340) parallel to each other.

5. The tracked undercarriage (100) according to claim 2, wherein said translation means comprise at least one hydraulic cylinder (400) acting on said sliding frame (200, 300), extension or contraction of said sliding frame causing a corresponding translation of the sliding frame (200, 300) with respect to the main frame (110).

6. The tracked undercarriage (100) according to claim 5, wherein said at least one beam (230, 240, 330, 340) of each opposing sliding frame (200, 300) comprises internal cavities (250, 350) communicating with each other housing said at least one hydraulic cylinder (400), and wherein the contraction or extension of said at least one cylinder (400) causes a sliding of one beam (230, 240) with respect to another (330, 340), thereby causing a reciprocal sliding of said two sliding frames (200, 300).

7. The tracked undercarriage (100) according to claim 5, wherein said at least one hydraulic cylinder (400) is of a double-acting type.

8. The tracked undercarriage (100) according to claim 1, wherein said second constraining means comprise at least one connecting pin (220, 320) between said longitudinal member (210, 310) and said structure (121, 131) of a respective track unit (120, 130), and wherein said at least one connecting pin (220, 320) is placed orthogonally to said first longitudinal direction (X) and identifies a rotation around said axis of rotation (Y1) of said track unit (120, 130) with respect to said sliding frame (200, 300).

9. The tracked undercarriage (100) according to claim 8, wherein the at least one connecting pin comprises two coaxial pins (220, 320) of said two opposing sliding frames (200, 300).

10. The tracked undercarriage (100) according to claim 5, wherein said rotation means (500) comprise at least one hydraulic cylinder (510) hinged between a fixed point (520) integral with said longitudinal member (210, 310) and at least one fixed point (530) integral with said structure (121, 131) of the track unit (120, 130), and wherein rotation axes of hinges of said at least one hydraulic cylinder (510) are parallel to said axis of rotation (Y1).

11. The tracked undercarriage (100) according to claim 5, wherein said at least one hydraulic cylinder (510) of each sliding frame (200, 300) is controlled by a hydraulic circuit which controls an operation of said at least one hydraulic cylinder selectively, independently and/or simultaneously with said hydraulic cylinder (510) of another sliding frame (300, 200) of said tracked undercarriage.

Description

[0030] The characteristics of the present undercarriage will be better clarified by the following description with reference to the drawings, attached by way of a non-limiting example.

[0031] FIG. 1 shows a three-dimensional view of just the tracked undercarriage (100).

[0032] FIG. 2 shows a schematic top view of the new tracked undercarriage (100) in its contracted configuration, where the sections of the two opposite sliding frames (200, 300) are visible.

[0033] FIG. 3 shows a schematic view from above of the new tracked undercarriage (100) in its extended configuration, where the sections of the two opposite sliding frames (200, 300) are visible.

[0034] The new tracked undercarriage (100) for operating machines comprising a main frame (110) defines a first longitudinal direction (X), which corresponds to the direction of movement of the undercarriage (100).

[0035] A tracked undercarriage (120, 130) is mounted on each of the two opposite sides (112, 113) of said main frame (110), positioned parallel to said first longitudinal direction (X).

[0036] Each track unit (120, 130) in turn comprises a structure (121, 131), at least one track (122, 132) mounted on said structure (121, 131), and a motor for driving said at least one track.

[0037] A sliding frame (200, 300) is interposed between each of said two opposite sides (112, 113) of said main frame (110) and one of said track units (120, 130).

[0038] Each of said sliding frames (200, 300) in turn comprises a longitudinal member (210, 310) placed parallel to said first longitudinal direction (X) and interposed between said main frame (110) and the corresponding track units (120, 130).

[0039] Each sliding frame (200, 300) also comprises at least one connecting pin (220, 320), which rotatably constrains the structure (121, 131) of a track unit (120, 130) to the corresponding longitudinal member (210, 310).

[0040] Said pin (220, 320) is placed orthogonally to said first longitudinal direction (X) so that said track unit (120, 130) can rotate with respect to the corresponding longitudinal member (210, 310) around the rotation axis (Y1) defined by said pin (220, 230).

[0041] Said two pins (220, 320) of the two opposite sliding frames (200, 300) are suitably aligned with each other.

[0042] Said sliding frames (200, 300) are also configured to slide with respect to the main frame (110) in a translation direction (Y) parallel to said rotation direction (Y1), that is, orthogonally to said first longitudinal direction (X).

[0043] More specifically, in the preferred embodiment shown in the figures, each of said sliding frames (200, 300) comprises at least one and preferably at least two beams (230, 240, 330, 340) placed parallel to said translation direction (Y) and slidingly housed in corresponding guides or seats (140, 150) made in said main frame (110).

[0044] FIGS. 2 and 3 show how the beams (330, 340) of a sliding frame (300) may be configured to slide inside corresponding cavities (250) made inside the beams (230, 240) of the opposing sliding frame (200).

[0045] The two sliding frames (200, 300) thus form a telescopic structure, where the two frames (200, 300) can slide with respect to each other between a contracted position, shown in FIG. 2, and an extended position, shown in FIG. 3.

[0046] In this embodiment, said beams (230, 240, 330, 340) of the two opposite sliding frames (200, 300) comprise internal cavities (250, 350), communicating with each other, housing at least one hydraulic cylinder (400), and where the contraction/extension of the cylinder (400) causes the sliding of one beam (230, 240) with respect to the other (330, 340), that is, it causes the two sliding frames (200, 300) to approach/move away from each other.

[0047] Said at least one hydraulic cylinder (400) is preferably of the double-acting type, with two chambers (420, 430) for the injection/suction of a fluid, indicated in FIGS. 2 and 3.

[0048] Said hydraulic cylinder (400) is therefore configured in such a way as to cause and control the simultaneous and symmetrical translation of both sliding frames (200, 300), with respect to each other and with respect to the main frame (110).

[0049] Each sliding frame (200, 300) further comprises rotation means (500) for controlling the variation of inclination of each track unit (120, 130) with respect to the main frame (110).

[0050] Said rotation means (500) comprise at least one hydraulic cylinder (510) hinged between a fixed point (520) integral with the relative longitudinal member (210, 310) and at least one fixed point (530) integral with said structure (121, 131) of the relative track unit (120, 130).

[0051] The rotation axes of the hinges in said fixed points (520, 530) of said at least one hydraulic cylinder (510) are parallel to said rotation axis (Y1) defined by said pin (220, 320). The extension/contraction of said hydraulic cylinder (510) therefore causes the rotation of the relative track unit (120, 130) with respect to the corresponding longitudinal member (210, 310), that is, with respect to said main frame (110), thus causing the variation of the inclination of each track unit (120, 130) with respect to the main frame (110).

[0052] Each of said hydraulic cylinders (510) of each of said sliding frames (200, 300) is controlled by its own hydraulic circuit, so that it is possible to control the inclination of each of said track units (120, 130) selectively, independently and/or simultaneously with the opposite track unit (130, 120).

[0053] Said hydraulic cylinder (510) may preferably be installed above said longitudinal member (210, 310) and oriented parallel to said first longitudinal direction (X).

[0054] Therefore, with reference to the preceding description and the attached drawings the following claims are made.