The present invention relates to vehicle suspensions, and more particularly relates to a suspension for a self-propelled agricultural sprayer.
One known self-propelled sprayer is provided with a suspension arrangement having each of four drive wheels of the sprayer suspended independently, one each at opposite ends of front and rear axles that are fixed to the main frame of the sprayer. The suspension for each of the wheels includes a large complicated, machined casting fixed to one end of an associated axle and which works together with expensive chrome spindles which telescope within upright sleeves defined by the casting so as to permit relative motion between the wheel and the axle.
Another known self-propelled sprayer avoids the costs associated with the machined casting and chrome spindles by suspending the axles by the provision of a pair of connecting rods coupled between the vehicle main frame and each of opposite ends of the axle, and by providing a fifth connecting rod that serves as a lateral stabilizer bar. This suspension design suffers from the drawback that the axle swings in an arc about the attachment points of the lateral stabilizer bar creating tracking issues as the suspension goes up and down.
Accordingly, the problem to be solved is that of providing a wheel suspension for a self-propelled sprayer which overcomes the drawbacks associated with the prior art suspensions.
According to the present invention, there is provided a vehicle axle suspension including a plurality of connecting rods.
An object of the invention is to provide a relatively simple vehicle axle suspension including suspension rods arranged in a manner for resulting in the opposite ends of the axle undergoing near vertical up and down motion as the vehicle travels over uneven ground.
The foregoing object is accomplished by suspending each end of the axle from the vehicle frame by a pair of connecting rods arranged such that as viewed from the side, they are connected in parallel, and as viewed from the top one crosses the other.
The foregoing and other objects will become apparent from a reading of the ensuing description together with the appended drawings.
Referring now to
The main frame 11 comprises transversely spaced, right- and left-hand, fore-and-aft extending parallel beams 14 and 16, respectively. The beams 14 and 16 are fixed relative to each other by cross members in the form of front and rear, generally V-shaped: suspension rod mounting brackets 18 and 20, respectively. The front bracket 18 is spaced to the rear from front ends of the beams 14 and 16 and has opposite vertical ends 22 and 24, respectively engaged with, and secured, as by bolts (not shown), against outer faces of the beams. The rear bracket 20 is spaced forwardly from rear ends of the beams 14 and 16 and has opposite vertical ends 26 and 28 respectively engaged with, and secured, as by bolts (not shown) against, the outer faces of the beams 14 and 16.
Extending beneath each of front and rear end regions of, and disposed crosswise relative to, the parallel beams 14 and 16 are front and rear axles 30 and 32, respectively. Referring now also to
Right and left hand front spindles (not visible) are respectively mounted for oscillating in the drop knees 36 and 38. Upper ends of the spindles 50 and 52 project from tops of the drop knees 36 and 38, and are respectively coupled, as by cap screws 50 and 52, to right and left steering arms 54 and 56. Formed integrally with the bottom ends of the spindles are wheel support and motor housings 58 and 60, with a hydraulic wheel motor 62 being bolted to a mounting surface 64 of each of the housings 58 and 60 and being coupled, in a manner not shown, for driving the front wheels 12. A right steering cylinder 68 is coupled between the right mounting arm 40 and the right steering arm 54, while a left steering cylinder 70 is coupled between the left mounting arm 42 and the left steering arm 56.
Mounted for oscillating in the drop knees 46 and 48 of the rear axle 32 are right and left rear spindles 72 and 74, respectively. Formed integrally with a bottom end of the spindles 72 and 74 are right and left wheel support and motor housings 76 and 78. A hydraulic drive motor 80 is bolted to an outwardly facing mounting surface (not shown) of each of the wheel support and motor housings 76 and 78, and is coupled for driving an associated one of the non-steerable rear wheels 13.
The front and rear axles 30 and 32 are respectively suspended from the main frame 11 by substantially identical front and rear suspension arrangements 84 and 86, which are mirror images of each other, with only the front suspension arrangement 84 being shown and described in detail for the sake of brevity.
The front suspension arrangement 84 comprises a middle suspension rod connection bracket joined to, and projecting rearwardly from, an upper central location of the middle section 34 of the front axle 30 and including a pair of right and left, upper suspension rod mounts 88 and 90, respectively. Located approximately midway between a right end of the axle middle section 34 and the right upper mount 88 is a right, lower suspension rod connection bracket including a right, lower suspension rod mount 92. Similarly, located approximately midway between a left end of the axle middle section 34 and the left upper mount 90 is a left, lower suspension rod mount 94. As viewed from the top in
Joined to and projecting forwardly from a lower middle location of the front suspension rod mounting bracket 18 is a pair of right and left lower suspension rod connection mounts 96 and 98, respectively. Respectively joined to, and projecting forwardly from, upper right and left end locations of the bracket 18 are an upper pair of suspension rod connection mounts 100 and 102. As viewed from the top in
An upper pair of right and left suspension rods 104 and 106 have forward ends respectively coupled to the upper pair of mounts 88 and 90, and have rear ends respectively coupled to the upper pair of mounts 100 and 102. Similarly, a lower pair of right and left suspension rods 108 and 110 have forward ends respectively coupled to the lower right and left suspension rod connection mounts 92 and 94, and have rear ends respectively coupled to the lower right and left suspension mounts 96 and 98.
As viewed from the side in
Up and down motion of the front axle 30 is cushioned by right and left airbags 112 and 114, having upper ends respectively coupled to right and left horizontal mounting plates 116 and 118 respectively fixed to and projecting outwardly from forward end regions of outer faces of the right and left beams 14 and 16; and having lower ends respectively coupled to right and left airbag connection by left and right airbag connection brackets (only left hand bracket 122 is visible) respectively projecting upwardly from right and left end regions of the central section 34 of the front axle 30. Further cushioning of up and down movement of the axle 30 is provided in conjunction with that afforded by the airbags 112 and 114 by right and left shock absorbers 124 and 126 having respective upper ends coupled to right and left upper mounts 128 and 130, respectively fixed to and projecting outwardly from the beams 14 and 16 at locations just forward of the airbag mounting plates 116 and 118, and having respective lower ends coupled to right and left lower mounts (only the right mount 132 is visible) respectively fixed to lower front locations, of the central axle section 34, which are in approximate vertical alignment with the upper mounts 128 and 130.
Up and down motion of the rear axle 32 is similarly cushioned by right and left rear airbags and right and left rear shock absorbers, with the drawings having only a clear showing of a left airbag 134 and a left shock absorber 136 (see
It will be appreciated then that the suspended front and rear axles 30 and 32 permit vertical movement of the axles making it unnecessary to provide expensive chrome spindles as are needed with the fixed axle design disclosed in the aforementioned U.S. Pat. No. 7,168,717. Further, it will be appreciated that by arranging the side-by-side sets of upper and lower suspension bars so that they each form an X, as viewed from the top, a substantially straight line or vertical up and down movement of the axle occurs which eliminates the arc motion generated from lateral stabilizer bars used in prior art suspensions, thus eliminating tracking issues that occur when the axle swings in ah arc about the attachment points of the lateral stabilizer bar.
While two pair of upper and lower suspension rods are used for each axle, it is noted that for some applications a single pair might provide an adequate axle suspension.
Having described the preferred embodiment, it will become apparent that various modifications can be made without departing from the scope of the invention as defined in the accompanying claims.