The invention herein described relates to a hydraulic apparatus and, more particularly, to a hydraulic apparatus including a circumferential arrangement of double-acting piston-cylinder assemblies.
Radial piston hydraulic motors are well known in the art. Such radial piston hydraulic motors include a plurality of cylinders oriented in a radial direction relative to a central axis of the motor. In some conventional radial piston hydraulic motors, the cylinders are formed in a cylinder block to which an output shaft is connected. The cylinder block rotates within a housing having an undulating inner cam surface. Each cylinder receives a piston assembly provided with a roller at its radially outer end that engages the undulating cam surface of the housing. During operation, hydraulic fluid pressure forces the pistons radially outward and this causes the rollers to roll over the undulating surface. Reactionary forces act on the cylinder block and cause it and the output shaft to rotate.
Other conventional radial piston hydraulic motors include an output shaft that is mounted on a centrally located eccentric cam. A plurality of piston-cylinder assemblies are located radially outwardly of the eccentric cam with one surface of either the piston or the cylinder engaging the eccentric cam. Hydraulic fluid pressure provided to a chamber within each cylinder acts on the piston to cause relative movement between the piston and the cylinder. The relative movement between the piston and the cylinder results in a force being applied to the eccentric cam by the engaging surface. This force causes rotation of the eccentric cam and thus rotation of the output shaft.
According to one aspect of the invention, a hydraulic apparatus comprises a housing having a central axis; a plurality of radially-oriented piston-cylinder assemblies each including a cylinder supported by the housing and a piston movable within the cylinder, the piston separating radially inner and outer chambers within the cylinder; and valving and associated flow passages for individually controlling the flow of hydraulic fluid to and from the radially inner and outer chambers of each piston-cylinder assembly.
According to another aspect of the invention, a hydraulic apparatus comprises a housing having a central axis; and a plurality of radially-oriented piston-cylinder assemblies each including a cylinder and a piston movable within the cylinder, wherein each cylinder is mounted to the housing for pivotal movement; each piston has a piston rod extending through a radially inner end of the respective cylinder, and the radially inner ends of the piston rods are connected to a rotatably mounted eccentric to which a drive shaft is connected.
The cylinder of each piston-cylinder assembly may have trunnions pivotally supported by the housing, and the trunnions may include respective flow passages connected to the inner and outer chambers of the respective cylinder. The housing may include axially separable parts with one trunnion of each cylinder disposed in a bearing in one housing part and the other trunnion disposed in a bearing in the other housing part. In addition, the housing parts may each include a circumferential array of recesses in which respective cylinders are free to pivot relative to the housing.
Each piston may have a piston rod extending through a radially inner end of the respective cylinder, and the radially inner ends of the piston rods may be connected to a rotatably mounted eccentric to which a drive shaft is connected. The valving and flow passages may include a plurality of valves movable radially in a valve housing, which valves are moved in between open and closed positions in timed sequence with rotational motion of the drive shaft. A cam may be connected to the drive shaft, and the valves may have cam followers engaging the cam whereby the valves are opened and closed in timed relationship to rotation of the drive shaft.
An inlet port may be provided for connection to a source of pressurized hydraulic fluid and an outlet port for connection to a hydraulic fluid return, for causing rotation of the drive shaft when the hydraulic apparatus is used as a motor. Alternatively, an inlet port may be provided for connection to a source of hydraulic fluid and an outlet port for supplying pressurized hydraulic fluid to an external component, for pumping hydraulic fluid when the drive shaft is rotatably driven by an external device.
The hydraulic apparatus may be axially stacked against at least one other said hydraulic apparatus with the radially inner ends of the piston rods connected to a rotatably mounted eccentric to which the drive shaft is connected.
Further features of the invention will become apparent from the following detailed description when considered in conjunction with the drawings.
In the annexed drawings,
Referring now in detail to the drawings and initially to
The hydraulic apparatus shown in
Referring now to
In the illustrated embodiment, the housing 24 of each drive module 22 has first and second parts or halves 32 and 33 that may be in the form of plates that may mate along a central plane of the housing. The housing parts support therebetween a circumferential and preferably coplanar arrangement of radially oriented piston-cylinder assemblies 35. The piston-cylinder assemblies 35, which may be identical to one another, may be circumferentially equally spaced apart in concentric relation to the center axis 37 of the housing 24.
In
As shown, the cylinder 46 may be provided with a pair of trunnions 50 and 51 whereby the cylinder may be mounted for pivotal movement in the housing 24 as discussed further below. The trunnions 50 and 51 preferably include respective flow passages 54 and 55 that connect respective ports 56 and 57 in the trunnions to flow passages in the cylinder that lead to the radially outer and inner chambers 46 and 45, respectively. The trunnion 50 may also be provided with inner and outer annular grooves 60 and 61 on opposite sides of the port 56 for sealing against leakage along the trunnion when the cylinder is mounted in the housing 24. The trunnion 51 may have a similar arrangement of grooves 62 and 63 for receiving seals.
Referring now to
Although not shown, the trunnion-receiving bores 69 and 70 have side ports for fluid communication with the ports 56 and 57 in the trunnions 50 and 51. The side ports in the bores in the housing part 32 connect to respective axial passages 73 in the housing part 32 and the side ports in the bores in the other housing part 33 connect to respective axial passages 74. The axial passages 73 and 74 in the housing parts connect with corresponding axial passages of one another, and the passage may extend between outer axial end surfaces of the housing 24 for connection with like passages in another drive module stacked in juxtaposition therewith, or to the valve module 23 or other flow control device. This arrangement provides for a ganged connection between one or more modules of the apparatus.
With the foregoing mounting arrangement of the piston-cylinder assemblies, the rods thereof all extend radially inwardly for connection to a eccentric cam or crank of a drive shaft 80. Such connection may be effected by engagement with a cam surface or by pivotal connection to the crank of the drive shaft, for example. When the hydraulic apparatus is operated as a motor, phased extension and retraction of the piston-cylinder assemblies effects rotation of the drive shaft. When the hydraulic apparatus is operated as a pump, rotation of the drive shaft will effect phased extension and retraction of the piston-cylinder assemblies.
In the hydraulic apparatus shown in
Phased movement of the spool valves 83 is coordinated (timed) with movement of the drive shaft 80. To this end, a timing cam 89 is provided. In the illustrated embodiment, the cam has a groove 89a in an axial end face with receives axial cam follower pins 90 connected to radially inner ends of the spool valves. As the cam rotates with the drive shaft, the spool valves will be controllably moved radially inwardly and outwardly for controlled supply of hydraulic fluid to and from the piston-cylinder assemblies 35.
Fluid flow to and from both chambers 45 and 46 of each piston-cylinder assembly 35, as above described, is controlled whereby the piston-cylinder assembly will be “double acting.” “Double acting” in the context of this application means that the piston-cylinder assembly may provide an output force during an up-stroke (radially outward movement of the piston) and during a down-stroke (radially inward movement of the piston). Since all of the upper surface of the piston 42 is available for contact with fluid within the radially outer chamber, a large displacement is available using the radially outer chamber. The piston rod 47 decreases the working area of the bottom surface of the piston. As a result, the displacement available using the radially inner chamber 45 is less then that available using the radial outer chamber 46 in the illustrated embodiment.
Various valve configurations may be associated with the hydraulic apparatus depending upon the desired use. The “double acting” piston-cylinder assemblies 35 enable three operating modes for the hydraulic apparatus. In a first operating mode, valving may be associated with the piston-cylinder assemblies for providing an output force during both the up-stroke and the down-stroke. In a second operating mode, valving may be associated with the piston-cylinder assemblies for providing an output force only during the up-stroke. In a third operating mode, valving may be associated with the piston-cylinder assemblies for providing an output force only during the down-stroke.
These various valve configurations may include arrangements other than that afforded by the above-described valve module 23. For instance, high speed, electronically controlled valves may be used during the “double acting mode” so that high pressure fluid may be input into one chamber during expansion of the chamber and the other chamber may be connected to an associated reservoir during contraction of that chamber.
Although the invention has been shown and described with respect to a certain preferred embodiment or embodiments, it is obvious that equivalent alterations and modifications will occur to others skilled in the art upon the reading and understanding of this specification and the annexed drawings. In particular regard to the various functions performed by the above described elements (components, assemblies, devices, compositions, etc.), the terms (including a reference to a “means”) used to describe such elements are intended to correspond, unless otherwise indicated, to any element which performs the specified function of the described element (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary embodiment or embodiments of the invention. In addition, while a particular feature of the invention may have been described above with respect to only one or more of several illustrated embodiments, such feature may be combined with one or more other features of the other embodiments, as may be desired and advantageous for any given or particular application.
This application claims the benefit of U.S. Provisional Application No. 60/725,397 filed Oct. 11, 2005, which is hereby incorporated herein by reference.
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Number | Date | Country | |
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