The present disclosure relates to a strut assembly for coupling an implement to a frame of the machine.
Machines, such as motor graders, are generally used for clearing materials, such as snow, accumulated on road surface or any other ground surfaces. For example, the motor grader includes an implement, such as a snow wing plow, attached to a frame of the motor grader in proximity to an operator cabin. The implement is coupled to the motor grader in a manner to extend a lateral snow plowing reach of the motor grader. In addition, the implement extends at an angle to a longitudinal axis of the motor grader for engaging with the ground surface. During snow plowing, an operator of the motor grader needs to watch for obstacles along the ground surface and raise the implement, to avoid striking the obstacles. However, in cases where the obstacles are buried by snow, or visibility is otherwise poor making it difficult for the operator to see the obstacle, striking of the implement with the obstacles may lead to application of high magnitude load on the implement. Accordingly, there is a need for the implement to uncouple from the frame of the machine to withstand the applied load and prevent the load from being transmitted to the frame of the machine.
JP Patent Number 3170683 (the '683 patent) discloses separated pieces of a shear pin from falling by freely fitting C-shaped rings into grooves in shear pin bushes so that inner diameters of the rings are slightly smaller than an outer diameter of the shear pin. The C-shaped rings are freely fitted into fitting grooves for the C-shaped rings inside of shear pin bushes. When the shear pin is inserted into the C-shaped rings, a suitable tightening force is generated by an elastic action of the C-shaped rings, and tightens and holds the shear pin. After the insertion, the shear pin is fixed at a position by a lock pin. In the shear pin bushes, side faces with high hardness agrees with shearing grooves of the shear pin by heat treatment. When the shear pin reaches the limitation of its shearing stress caused by overload on a body, the shear pin is sheared and separated.
According to an aspect of the present disclosure, a strut assembly for coupling an implement to a frame of a machine is provided. The strut assembly includes a first elongated member configured to couple to the frame of the machine. The strut assembly further includes a second elongated member slidably disposed within the first elongated member. The second elongated member is configured to couple to the implement. The strut assembly further includes a shear system configured to engage the second elongated member with the first elongated member. The shear system includes a first shear pin configured to be inserted through a first opening defined in the first elongated member and a second opening defined in the second elongated member. The first shear pin includes a first fracture zone positioned within a gap defined between the first elongated member and the second elongated member.
In another aspect of the present disclosure, a strut assembly for coupling an implement to a frame of a machine is provided. The strut assembly includes a first elongated member configured to couple to the frame of the machine. The strut assembly further includes a second elongated member slidably disposed within the first elongated member. The second elongated member is configured to couple to the implement. The strut assembly further includes a linear actuator coupled to the frame of the machine, and is configured to move the first elongated member relative to the frame. The strut assembly further includes a first shear system configured to engage the second elongated member with the first elongated member. The first shear system includes a first shear pin supported on a clamping member, and is configured to be inserted through a first opening defined in the first elongated member and a second opening defined in the second elongated member. The first shear pin includes a first fracture zone positioned within a gap defined between the first elongated member and the second elongated member. The strut assembly further includes a second shear system configured to engage the second elongated member with the linear actuator. The second shear system includes a first mounting bracket coupled to the first elongated member. The second shear system further includes a second mounting bracket coupled to the linear actuator, and is slidably received within the first mounting bracket. The second shear system further includes a sliding pin coupled to the second mounting bracket, and is configured to slidably receive through an elongated slot defined in the first mounting bracket. The second shear system further includes a shear member configured to be inserted through a first hole defined in the first mounting bracket and a second hole defined in the second mounting bracket, and is configured to engage the first mounting bracket with the second mounting bracket.
In yet another aspect of the present disclosure, a machine is provided. The machine includes a frame and a first elongated member configured to couple to the frame. The strut assembly further includes a second elongated member slidably disposed within the first elongated member. The second elongated member is configured to couple to the implement. The strut assembly further includes a linear actuator coupled to the frame of the machine, and is configured to move the first elongated member relative to the frame. The strut assembly further includes a first shear system configured to engage the second elongated member with the first elongated member. The first shear system includes a first shear pin supported on a clamping member, and is configured to be inserted through a first opening defined in the first elongated member and a second opening defined in the second elongated member. The first shear pin includes a first fracture zone positioned within a gap defined between the first elongated member and the second elongated member. The strut assembly further includes a second shear system configured to engage the second elongated member with the linear actuator. The second shear system includes a first mounting bracket coupled to the first elongated member. The second shear system further includes a second mounting bracket coupled to the linear actuator, and is slidably received within the first mounting bracket. The second shear system further includes a sliding pin coupled to the second mounting bracket, and is configured to slidably receive through an elongated slot defined in the first mounting bracket. The second shear system further includes a shear member configured to be inserted through a first hole defined in the first mounting bracket and a second hole defined in the second mounting bracket, and is configured to engage the first mounting bracket with the second mounting bracket.
Other features and aspects of this disclosure will be apparent from the following description and the accompanying drawings.
Reference will now be made in detail to specific embodiments or features, examples of which are illustrated in the accompanying drawings. Wherever possible, corresponding or similar reference numbers will be used throughout the drawings to refer to the same or corresponding parts. Moreover, references to various elements described herein, are made collectively or individually when there may be more than one element of the same type. However, such references are merely exemplary in nature. It may be noted that any reference to elements in the singular may also be construed to relate to the plural and vice-versa without limiting the scope of the disclosure to the exact number or type of such elements unless set forth explicitly in the appended claims.
The machine 100 further includes a hydraulic system 114 for actuating the implement 110 and other operating systems including, but not limited to, a steering system of the machine 100. The hydraulic system 114 may include various components including, but not limited to, a reservoir, one or more hydraulic pumps, one or more direction control valves, and other control valves for supplying hydraulic fluid at a desired pressure to the various components of the machine 100. The one or more hydraulic pumps of the hydraulic system 114 are operatively coupled with the engine to receive power therefrom to supply pressurized hydraulic fluid.
The implement 110 of the machine 100 is used for removing materials, such as snow or soil, from the ground surface or the roadways. Further, the implement 110 is coupled to one side of the machine 100, such that the materials lying on the side of the machine 100 may be removed. The implement 110 may be used for removing the materials from the ground surface to a width greater than a width of the machine 100. The implement 110 includes a first end 116 and a second end 118. The first end 116 of the implement 110 is coupled to the frame 108 of the machine 100, via a linkage assembly 120. The linkage assembly 120 is configured to raise and lower the implement 110 with respect to the ground surface. Further, the linkage assembly 120 is configured to move the implement 110 to various angular positions with respect to the frame 108. The second end 118 of the implement 110 is coupled to the frame 108 via the strut assembly 102, as shown in
The strut assembly 102 is configured to move the implement 110 with respect to the linkage assembly 120 to the various angular positions. The strut assembly 102 includes a first elongated member 122 and a second elongated member 124 slidably disposed within the first elongated member 122. The first elongated member 122 is configured to couple to the frame 108 of the machine 100 and the second elongated member 124 is configured to couple to the implement 110.
The strut assembly 102 and the linkage assembly 120 are in fluid communication with the hydraulic system 114 of the machine 100. Based on an operator input, the hydraulic system 114 aids in actuation of the strut assembly 102 and the linkage assembly 120, thereby causing the implement 110 to move with respect to the ground surface during material removal operations.
An enlarged view of the first shear system 202 is shown in
The first holding member 310 is mounted on the first elongated member 122 and configured to removably receive the first portion 304 of the first shear pin 302. For the purpose of supporting the first portion 304, the first holding member 310 includes a support member 312, and a first arm 314 and a second arm 316 extending from the support member 312. The support member 312 is fixed on the first elongated member 122 and extends from a surface of the first elongated member 122. Further, the first arm 314 and the second arm 316 extend in a direction perpendicular to the support member 312, such that the first arm 314 and the second arm 316 are separated by a distance ‘X’. In an example, the distance ‘X’ may be equal to or greater than a diameter of the first portion 304 of the first shear pin 302. That is, the first portion 304 of the first shear pin 302 may be inserted between the first arm 314 and the second arm 316 of the first holding member 310.
Although
Coupling of the first elongated member 122 with the second elongated member 124 by the first shear pin 302 will be described with reference to
The first shear system 202 further includes an annular member 406 coupled to the second portion 306 of the first shear pin 302. In one example, the annular member 406 may be embodied as a spacer, such that the second portion 306 of the first shear pin 302 passes coaxially through the spacer. In another example, the annular member 406 may be embodied as fins that protrude from the surface of the second portion 306 of the first shear pin 302. Further, in an embodiment, the first shear system 202 includes a first clamping member 408 configured to position the first shear pin 302 at a predetermined depth in the first elongated member 122 and the second elongated member 124. The first clamping member 408 is embodied as a cylindrical body having an aperture 410. The first clamping member 408 is mounted on the first elongated member 122 in such a way that the aperture 410 of the first clamping member 408 is aligned with the first opening 402 of the first elongated member 122. However, diameter of the aperture 410 may be equal to or greater than the diameter of the first opening 402. The first clamping member 408 provides support to the second portion 306 while the first shear pin 302 is being inserted through the first opening 402. In one example, the first clamping member 408 may be made of an reinforced elastomeric material, so that the second portion 306 may be rigidly held by the first clamping member 408.
The first shear pin 302 further includes a first fracture zone 412. In one example, the first fracture zone 412 can include a first annular notch 414. The first annular notch 414 has a cross-section narrower than the cross-section of the second portion 306 of the first shear pin 302. As illustrated in
As mentioned earlier, the second elongated member 124 is slidably disposed in the first elongated member 122 due to a difference in diameter between the first elongated member 122 and the second elongated member 124. Accordingly, during sliding movement of the second elongated member 124 in the first elongated member 122, a gap ‘G’ is maintained, along a radial direction, therebetween. In one example, the gap ‘G’ may be of one-fourth of an inch. In an embodiment, the strut assembly 102 further includes an annular spacer 416 disposed between an inner surface ‘S2’ of the first elongated member 122 and an outer surface ‘S3’ of the second elongated member 124. The annular spacer 416 is configured to define the gap ‘G’ between the first elongated member 122 and the second elongated member 124. In an example, the annular spacer 416 may be a ring that is disposed coaxially on the second elongated member 124. Further, a thickness of the annular spacer 416 may be equal to the difference in an inner diameter ‘Di’ of the first elongated member 122 and an outer diameter ‘Do’ of the second elongated member 124. In such an arrangement, the gap ‘G’ may be varied based on the thickness of the annular spacer 416. Further, the annular spacer 416 may be attached coaxially to the first elongated member 122, so that the annular spacer 416 is prevented from any displacement during a normal condition of the strut assembly 102. Further, the annular spacer 416 can also prevent sand particles, dust, and gravel, from entering into the gap ‘G’.
With such an arrangement, the first fracture zone 412 is positioned at a desired depth in the gap ‘G’. When the annular member 406 is coupled at the predetermined position on the first shear pin 302, the thickness of the first clamping member 408 may assist in positioning the first fracture zone 412 at the desired depth. Further, in an embodiment, the first shear pin 302 includes a third portion 418 that extends from the second portion 306. The third portion 418 is configured to extend through the second opening 404 defined in the second elongated member 124. The first fracture zone 412 is positioned between the second portion 306 and the third portion 418 of the first shear pin 302. As such, the cross-section of the first shear pin 302 decreases at the first fracture zone 412, while the cross-section of the second portion 306 and the third portion 418 remains the same.
The third portion 418 of the first shear pin 302 is configured to shear off at the first fracture zone 412, when load acting on the implement 110 exceeds a threshold capability of the first shear pin 302, as shown in
With reference to
A sectional view of the strut assembly 102 taken along line B-B′ of
Owing to further movement of the second elongated member 124 in the inward direction ‘D3’, a second end 804 of the longitudinal slot 614 approaches the second shear pin 602 at the second position ‘P2’ of the second elongated member 124. Further progressive movement of the second elongated member 124 in the inward direction ‘D3’ causes a third portion 902 of the second shear pin 602 to shear off, as shown in
In yet another embodiment of the present disclosure, the second elongated member 124 may include two or more longitudinal slots on a periphery of the second elongated member 124.
In such an arrangement, the first shear pin 302 is inserted through the first opening 402 and the primary longitudinal slot 1002 to engage the first elongated member 122 with the second elongated member 124.
In an inserted condition of the first shear pin 302, a first end 1114 of the primary longitudinal slot 1002 is in contact with the first section 1106 of the third portion 418 and a second end 1116 of the primary longitudinal slot 1002 is distal from the first section 1106 of the third portion 418 due to the length of the primary longitudinal slot 1002. At a diagonally opposite end, a first end 1118 of the secondary longitudinal slot 1004 is distant from the second section 1108 of the third portion 418 and a second end 1120 of the secondary longitudinal slot 1004 is in contact with the second section 1108 of the third portion 418. A point at which the second end 1120 of the secondary longitudinal slot 1004 contacts the second section 1108 of the third portion 418, lies above the third fracture zone 1104. In order to achieve such an arrangement within the second elongated member 124, the annular member 406 can be coupled at a predetermined location on the first shear pin 302. Alternatively, the thickness of the first clamping member 408 can be varied to assist in positioning the fracture zones at desired depths.
Further, as described earlier, when the implement 110 encounters the obstruction during the movement of the machine 100, load applied by the obstruction on the implement 110 causes the second elongated member 124 to slide in the inward direction ‘D3’ with respect to the first elongated member 122. Owing to such movement of the second elongated member 124 in the inward direction ‘D3’, the second end 1120 of the secondary longitudinal slot 1004 pushes the second section 1108 in the direction of movement of the second elongated member 124. Since the third section 1110 is restricted to movement by the fourth opening 1111 and the third clamping member 1112, the third section 1110 shears off at the third fracture zone 1104, from the second section 1108, when the second elongated member 124 moves in the inward direction ‘D3’, as shown in
Further movement of the second elongated member 124 in the inward direction ‘D3’ causes the second section 1108 to shear off at the second fracture zone 1102, as shown in
In one implementation, the strut assembly 102 further includes a damping member 1502 disposed around the second elongated member 124, as shown in
In addition, the first collar 1504 is disposed at a predetermined distance from the second end 206 of the first elongated member 122. When the implement 110 encounters the obstruction, the second elongated member 124 moves in the inward direction ‘D3’ to cause the third portion 418 of the first shear pin 302 to shear off. On covering the predetermined distance, the first collar 1504 is restricted in movement by the annular spacer 416. Accordingly, any further movement of the second elongated member 124 in the inward direction ‘D3’ causes the damping member 1502 to compress against the first collar 1504. As such, the damping member 1502 absorbs any further shocks which may be transmitted through the implement 110.
The second shear system 1602 further includes a second mounting bracket 1630 coupled to the first mounting bracket 1606. The second mounting bracket 1630 is accommodated in the predetermined distance defined by the first flange 1608 and the second flange 1610 of the first mounting bracket 1606. For the purpose of coupling, the second mounting bracket 1630 is slidably received within the first mounting bracket 1606.
The strut assembly 102 further includes a linear actuator 1632. The linear actuator 1632 is coupled to the frame 108 of the machine 100. The linear actuator 1632 is configured to move the first elongated member 122 with respect to the frame 108 of the machine 100. The hydraulic system 114 supplies hydraulic fluid at desired pressure to the linear actuator 1632 through one or more control valves. In an example, the one or more control valves may either be electrically actuated or mechanically actuated. Further, a control lever (not shown) may be provided in the operator cabin 106 for actuating the one or more control valves. The second shear system 1602 is configured to engage the first elongated member 122 with the linear actuator 1632. The second mounting bracket 1630 is coupled to the linear actuator 1632 by a fastening member 1634. In an example, the second mounting bracket 1630 may be coupled to the linear actuator 1632 by the fastening member 1634 or any other fastening methods known in the art.
The second shear system 1602 further includes a sliding pin 1706 coupled to the second mounting bracket 1630. The sliding pin 1706 is configured to be slidably received in the elongated slot 1629 defined in the first flange 1608. In an example, the sliding pin 1706 may be a fastening member, such as a bolt and a rivet. Although
The second shear system 1602 further includes a shear member 1708 configured to be inserted through the first hole 1616 defined in the first mounting bracket 1606 and the first through-hole 1702 defined in the second mounting bracket 1630. The shear member 1708 is configured to engage the first mounting bracket 1606 with the second mounting bracket 1630. In an embodiment, the second shear system 1602 further includes a second holding member 1710 to support and position the shear member 1708, when the shear member 1708 is employed to engage the first mounting bracket 1606 with the second mounting bracket 1630. The second holding member 1710 is mounted on the first flange 1608 and configured to removably receive the shear member 1708. For the purpose of supporting the shear member 1708, the second holding member 1710 includes a support member 1712, and a first arm 1714 and a second arm 1716 extending from the support member 1712. The support member 1712 is fixed on the first flange 1608 and extends from a surface of the first flange 1608. Further, the first arm 1714 and the second arm 1716 extend in a direction perpendicular to the support member 1712.
In cases where the implement 110 encounters the obstacle, the load applied by the obstacle on the implement 110 may cause the implement 110 to be displaced in a direction vertical with respect to the ground surface. Due to such vertical movement of the implement 110, the strut assembly 102 gets displaced angularly. In other words, the strut assembly 102 is displaced from a first angular position ‘A1’ to a second angular position ‘A2’. In one example, the angular displacement may be about 10 degrees. Owing to such angular displacement of the strut assembly 102, the first mounting bracket 1606 also gets displaced angularly. In such a condition, the second mounting bracket 1630 is linearly displaced along the width of the first and second flange 1608, 1610 respectively. A combination of the angular displacement and the linear displacement causes a relative movement between the first mounting bracket 1606 and the second mounting bracket 1630, resulting in shearing off the shear member 1708 as shown in
In one implementation, the shear member 1708 may include one or more fracture zones (not shown). For instance, the shear member 1708 may extend to a predefined length from the first flange 1608. In such a scenario, the fracture zone of the shear member 1708 may be positioned at a juncture between the first flange 1608 and the second mounting bracket 1630. The fracture zones aids in easy shearing of the shear member 1708 to allow movement of the first mounting bracket 1606 with respect to the second mounting bracket 1630. Further, the operator of the machine 100 may choose to use the shear member 1708 for engaging the first mounting bracket 1606 with the second mounting bracket 1630 for smooth operation of the implement 110. However, in cases where the shear member 1708 is not used, the implement 110 could cause the strut assembly 102 to float vertically with respect to the ground surface, thereby causing the implement 110 to trace an uneven path on the ground surface. For the purpose of replacing the shear member 1708 when sheared, an additional shear member (not shown) may be disposed in the first mounting bracket 1606. For example, the additional shear member may be disposed through the second hole 1618 of the first flange 1608 and the second hole 1626 of the second flange 1610.
Various embodiments disclosed herein are to be taken in the illustrative and explanatory sense, and should in no way be construed as limiting of the present disclosure.
The present disclosure relates to the strut assembly 102 for coupling the implement 110 to the frame 108 of the machine 100. Owing to the presence of the first shear system 202 and the second shear system 1602, impact caused by the obstacle, on the implement 110, during the movement of the machine 10 is restricted from transferring to the frame 108 of the machine 100 due to shearing of the first shear pin 302 and the second shear pin 602 of the respective first and second shear systems 202, 1602. As such, the impact is prevented from being transmitted to the frame 108 of the machine 100, and resetting of the first and second shear systems 202, 1602 after shearing of the first and second shear pin 302, 602, respectively, become easy for an operator.
The sheared pin or the shear member can be easily replaced with the additional shear member by raising or lowering the implement to a predetermined height, which otherwise required more efforts by the operator of the machine 100. Such configuration of the strut assembly 102 of the present disclosure provides a cost effective means for coupling the implement 110 to the frame 108 of the machine 100. The configuration of the strut assembly 102 eliminates the requirement of a strut retaining cable, which was otherwise employed to support the strut assembly 102.
As described above, according to one embodiment of the present disclosure, the first shear pin 302 for engaging the first elongated member 122 with the second elongated member 124 is provided. The shearing of the first shear pin 302 minimizes shock and load from being transmitted from the implement 110 to the machine 100. According to another embodiment of the present disclosure, the first shear pin 302 extends along the diameter of the first elongated member 122 and the second elongated member 124. Such configuration of the first shear pin 302 allows stage-wise shearing of the first shear pin 302, thereby minimizing magnitude of shock or load transmitted from the implement 110 to the machine 100.
According to yet another embodiment of the present disclosure, the second shear pin 602 is provided in addition to the first shear pin 302. The second shear pin 602 aids in further minimizing the impact being transmitted from the implement 110 to the machine 100. In addition, the longitudinal slot 614 and the second shear pin 602 allows for travel of the second elongated member 124 before shearing the second shear pin 602. Furthermore, according to yet another embodiment of the present disclosure, the second shear system 1602 is provided. The shear member 1708 of the second shear system 1602 aids in further minimizing the impact being transmitted from the implement 110 to the machine 100. As such, the magnitude of the impact is almost nullified, thereby preventing any damage to the machine 100.
While aspects of the present disclosure have been particularly shown and described with reference to the embodiments above, it will be understood by those skilled in the art that various additional embodiments may be contemplated by the modification of the disclosed machines, systems and methods without departing from the spirit and scope of what is disclosed. Such embodiments should be understood to fall within the scope of the present disclosure as determined based upon the claims and any equivalents thereof.
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Number | Date | Country | |
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20170247855 A1 | Aug 2017 | US |