A Multi-functional Engineering Attachment for Clamping, Cutting, and Grasping With A Single Degree Of Freedom Variable Topology Mechanism

Abstract

The invention discloses a clamping-cutting-grasping multi-functional engineering attachment applying single-degree-of-freedom shape-shifting mechanism, having a symmetrical structure, comprising: a clamping and cutting device, a grasping device, and a separating and deforming device; further comprises two hydraulic cylinders, one base, two separation bases, a driving hydraulic cylinder, hydraulic scissors, a grasping connecting rod, a grasping claw, a separating connecting rod, a base guide rod, a base slider, a separating slider, first connecting rod, second connecting rod and separation slider track groove. The invention uses a double slider mechanism to achieve the relative movement between the grasping device versus the clamping and shearing device, and also realizes a fast conversion from clamping and cutting device to the grasping device, all the work requirements being satisfied under each working state without motion interference.

Claims

1. A multi-functional engineering attachment for clamping, cutting and grasping with single-degree of freedom variable topology mechanism, comprising: two hydraulic cylinders (1), a base (2), two separating bases (3), driving hydraulic cylinder (4), hydraulic scissor (5), a grasping connecting rod (6), a grasping claw (7), a separating connecting rod (8), a base guide rod (9), a base slider (10), separating slider (11), first connecting rod (12), second connecting rod (13) and a separating slider track groove (14); wherein, the overall appearance of the hydraulic scissors (5) is a triangular plate structure with teeth on one side, and with three angles referenced as A, B and C, wherein a sideline connecting the angle A and the angle C has teeth; the overall appearance of the structure of the grasping claw (7) is a triangular plate with three angles referenced as A, B and C, wherein the angle C has a hook as the tip of the claw. the hydraulic scissors (5) and the grasping claw (7) are matched in pairs; the axial directions of the two hydraulic cylinders (1) are arranged in a plane in parallel, one end of one hydraulic cylinder is staggered opposite to one end of the other hydraulic cylinder, wherein the two staggered opposite ends are respectively fixed with the upper part of the separating bases (3), the other ends of the two hydraulic cylinders (1) are fixed onto the base (2), the two hydraulic cylinders (1) are configured to push the two separating bases (3) to move along the axes of two hydraulic cylinders (1) respectively during working state, with the two separating bases (3) moving in opposite directions; assigning the left and right axial directions of the two hydraulic cylinders (1) as the direction of the X axis, vertical direction as the Y-axis direction, and a direction perpendicular to the X-axis and Y-axis as the Z-axis, which is also the axial direction of multi-functional engineering attachment for clamping, cutting and grasping; thereafter, the separating bases (3) are arranged symmetrical along the Y-axis, the lower ends of the separating bases (3) have a triangular deletion along the Z-axis, and the middle and lower parts of the separating base (3) have grooves on two sides along the X axis; for the structure along the X-axis side, the lower part of the separating bases (3) have a through hole along the z-axis direction, and the first connecting rod (12) is installed in the through hole and parallel to the Z-axis, the bottom grooves of the separating bases (3) are connected to angle A of the hydraulic scissors (5) by means of a hinge, respectively, the hinge between the separating base (3) and the hydraulic scissors (5) angle A is lower than the first connecting rod (12) in Z-axis direction. The groove in the middle part of the separating bases (3) is fixed to one end of the driving hydraulic cylinder (4), the other end of the driving hydraulic cylinder (4) is connected to angle B of the hydraulic scissors (5) by means of a hinge. The separation bases (3), the driving hydraulic cylinder (4) and the hydraulic scissors (5) constitute a three-bar structure. The first connecting rod (12) outside the Z-axis direction of separating base (3) is connected by a hinge with angle A of the grasping claw (7) through the separating connecting rod (8), the separating slider (11) is provided protruding from the outside the angle A of the grasping claw (7) along the direction of Z axis, the separating slider (11) is located inside of the vertical and rectangular separating slider track groove (14), the separating slider (11) can slide up and down, and the separating slider track groove is fixed to the base (2). A through hole is provided in the grasping claw (7) angle B along the Z-axis, the second connecting rod (13) is installed through the through hole. The second connecting rod (13) is parallel to Z-axis, and the grasping connecting rod (6) is adopted to connect the hydraulic scissors (5) angle B and the second connecting rod (13). The hydraulic scissors (5) angle B and the grasping connecting rod (6) are connected by hinge, the second connecting rod (13) is rotatably connected to the grasping connecting rod (6); and the base slider (10) is fixed onto and protrudes from the outer side and along Z-axis of the separating base (3), a through hole is installed in the inner part of the base slider (10) along the X-axis. The base guide rod (9) is installed through the through hole and is parallel to X-axis, the two ends of the base guide rod (9) are fixed on the base (2).

2. The multi-functional engineering attachment for clamping, cutting and grasping with single-degree of freedom variable topology mechanism according to claim 1, wherein the grasping claw (7) is a multi-pair grasping claw parallel to the Z-axis.

3. The multi-functional engineering attachment for clamping, cutting and grasping with single-degree of freedom variable topology mechanism according to claim 1, wherein the multi-function attachment is equipped with a clamping and cutting device A, a grasping device B, and a separating and deforming device C; wherein, when the attachment functions as the clamping and cutting device A, the separating bases (3) are integrated with the base (2), at the same time, the separation bases (3) function as a frame and forms a four-bar mechanism with the driving hydraulic cylinder (4) and hydraulic scissors (5). The driving hydraulic cylinder (4) provides power and drives the hydraulic scissors (5) to achieve the function of cutting and crushing; when the attachment functions as the grasping device B, the separating slider (11) and the separating bases (3) are integrated with the base (2), which are regarded or function as a frame; at the same time, the driving hydraulic cylinder (4) provides the driving force, with the help of the rotation of the hydraulic scissors (5), with the hydraulic scissors (5) and the grasping claw (7) as the frame connecting rod, with the grasping connecting rod (6) as connecting rod, a four-bar mechanism is formed to drive the grasping claw (7) to achieve the grasping function; when the attachment functions as the separating and deforming device C, the driving hydraulic cylinder (4) needs to be locked, that is, the clamping and cutting device A is a component: the hydraulic cylinder (1) is used as the driver during the separation deformation, the separating and deforming device C is a double slider mechanism; and the change of positions of two sliders causes changes in the configuration of the four-bar mechanism with the hydraulic scissors (1) and the grasping claw (7) as frame connecting rod, and the grasping claw as the connecting rod, achieving the conversion among the crushing function, cutting function and grasping function.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] FIG. 1 is a diagram showing 3D front view of the entire assembly, according to one embodiment;

[0024] FIG. 2 a diagram showing 3D side view of the entire assembly, according to one embodiment;

[0025] FIG. 3a diagram showing 3D axonometric view of the entire assembly, according to one embodiment;

[0026] FIG. 4a diagram showing front view of the clamping and cutting device, according to one embodiment;

[0027] FIG. 5a diagram showing side view of the clamping and cutting device, according to one embodiment;

[0028] FIG. 6a diagram showing axonometric view of the clamping and cutting device, according to one embodiment;

[0029] FIG. 7a diagram showing details of the clamping and cutting edge, according to one embodiment;

[0030] FIG. 8a diagram showing front view of the grasping device, according to one embodiment;

[0031] FIG. 9a diagram showing side view of the grasping device, according to one embodiment;

[0032] FIG. 10a diagram showing axonometric view of the grasping device, according to one embodiment;

[0033] FIG. 11a diagram showing front view of the separating and deforming device, according to one embodiment;

[0034] FIG. 12a diagram showing axonometric view of the separating and deforming device, according to one embodiment;

[0035] FIG. 13a diagram showing details of the separating slider, according to one embodiment;

[0036] FIG. 14a diagram showing details of the hydraulic cylinder, according to one embodiment;

[0037] FIG. 15a diagram showing the closing state, according to one embodiment;

[0038] FIG. 16a diagram showing the separating state, according to one embodiment;

[0039] FIG. 17a diagram showing working diagram of crushing, according to one embodiment;

[0040] FIG. 18a diagram showing working diagram of clamping and cutting, according to one embodiment;

[0041] FIG. 19a diagram showing Initial working location of grasping, according to one embodiment; and

[0042] FIG. 20a diagram showing working diagram of grasping, according to one embodiment.

[0043] Wherein 1. Hydraulic cylinder 2.Base 3.Separating bases 4. Driving hydraulic cylinder. 5.Hydraulic scissor 6.Grasping connecting rod 7.Grasping claw 8.Separating connecting rod 9.Base guide rod 10.Base slider 11.Separating slider 12.First connecting rod. 13.Second connecting rod. 14.Separating slider track groove.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0044] The specific embodiments are described accompanied with the attached drawings, but the invention is not limited to the following embodiments.

Embodiment 1

[0045] As shown in FIGS. 1, 2 and 3, a type of multi-functional rescue attachment for clamping, cutting and grasping is disclosed, including the clamping and cutting device A, the grasping device B and the separating and deforming device C. the attachment has three kinematic states: cutting and crushing; grasping; separating and deforming.

[0046] As shown in FIGS. 15 and 16, the attachment is in the separating and deforming state. When the attachment is under the separating and deforming state, the driving hydraulic cylinder (4) should be locked, based on FIG. 4, the clamping and cutting device A can be considered as a component of the attachment.

[0047] Thereupon, the lamping and cutting device A, the separating connecting rod (8), the base (2) and the separating slider (11) constitute a double slider mechanism. As shown in FIGS. 15 and 16, the clamping and cutting device A, the separating connecting rod (8), the grasping connecting rod (6) and grasping claw (7) also constitute a “abcd” four-bar mechanism. To facilitate illustration, the base (2) should not be regarded as the frame, instead the clamping and cutting device A can be regarded as the frame. The hydraulic cylinder (1) is pushed out to make the clamping and cutting device A move along the direction of the separating base slider (3). The translation of the base (2) relative to the clamping and cutting device A causes the separating connecting rod (8) to rotate around point c, the rotation of the separating connecting rod (8) causes the “abcd” four-bar mechanism to move. The movement results in a change in the relative position of the grasping claw (7) and the hydraulic scissors (5), that is, the changes of the posture of four-bar mechanism and the length of the “be” components. When the hydraulic cylinder (1) reaches the appropriate position, lock the hydraulic cylinder (1) to complete the separation action. Closing movement is realized by reverse driving direction of the hydraulic cylinder (1). FIG. 15 shows the attachment after the completion of a closing action, and FIG. 16 shows the attachment after completion of a separation action.

[0048] As shown in FIGS. 1 and 17, the multi-functional attachment is in the cutting and crushing state. Before cutting and crushing, closing action should be completed and the hydraulic cylinder (1) should be locked. So that the base (2) and the separating base (3) are regarded as a single component of the attachment. The separating bases 3, the driving hydraulic cylinder (4) and the hydraulic scissors (5) constitute a four-bar mechanism. The driving hydraulic cylinder (4) is the power source to push the hydraulic scissors (5) to achieve the function of cutting and crushing.

[0049] As shown in FIG. 18, the clamping and cutting device A is in the cutting state, cutting is realized by using the cutting edge in the hydraulic scissors (5). As shown in FIG. 1 and 17, the clamping and cutting device A is in the crushing state, crushing is realized by using the jaw in the outer part the hydraulic scissors (5).

[0050] As shown in FIGS. 19 and 20, the multi-functional attachment is in the grasping state. Before grasping, the separating action should be completed and the hydraulic cylinder (1) should be locked. Thus, the separating base (3), the separating slider (11) and the base (2) will not move relative to each other. The hydraulic scissors (5), the grasping claw 7 and the grasping connecting rod (6) constitute a “abed” four-bar mechanism. The driving hydraulic cylinder (4) is the main power source to promote the hydraulic scissors (5) to rotate to drive the rotation of the grasping claw (7). That is, the driving hydraulic cylinder (4) pushes the connecting rod “ed” to rotate around point “e”, through the transmission of the “abed” four-bar mechanism, the connecting frame bar “ab” rotates around point “b” to achieve the grasping function.