The present invention relates to hydraulically driven motors, and more particularly relates to a gerotor motor having check valves incorporated into a thrust plate of the motor allowing bi-rotational operation with or without a case drain.
Hydraulic motors and gerotors are generally well known, some examples of which may be seen in the following patents:
U.S. Pat. No. 4,480,972 issued Nov. 6, 1984 to Eaton Corporation.
U.S. Pat. No. 6,193,490 issued Feb. 27, 2001 to White Hydraulics, Inc.
U.S. Pat. No. 4,362,479 issued Dec. 7, 1982 to Eaton Corporation.
U.S. Pat. No. 6,174,151 issued Jan. 16, 2001 to The Ohio State University Research Foundation.
While the prior art provides an array of hydraulic motors with varying operational capabilities and efficiencies, there remains a need for a simplified hydraulic motor which may be operated in either the clockwise or counter-clockwise direction with an optional case drain as needed for the particular application requirements.
The present invention addresses the above need by providing a hydraulic motor in the form of a gerotor motor having first and second ports which may be alternately and selectively used as inlet and outlet ports. Thus, to obtain a clockwise rotation of the motor shaft, the first port is connected to a source of pressurized fluid and thus acts as the inlet port while the second port acts as the outlet port. To obtain a counter-clockwise rotation of the motor, the source of pressurized fluid is connected to the second port and the first port acts as the outlet port.
Check valves are provided in a thrust plate located between the seal area of the motor output shaft and gerotor assembly. The check valve located at the inlet port will close due to the pressure in this area being higher than at the seal area. The check valve at the outlet port will open when the pressure at the outlet port is lower than at the seal area. Should the pressure at the seal area rise, the check valve opens and excess lubrication fluid from the seal area travels through the valve aperture in the thrust plate and empties into the output flow existing at the outlet port. An optional case drain is also provided that is in fluid communication with the seal area via a longitudinally extending bore in the motor shaft. If the application requires a case drain, the plug is removed and excess lubrication fluid is allowed to drain through the case drain outlet. If the case drain is not required, the plug is attached to the case drain outlet port.
Referring to the drawing, there is seen in the Figures one embodiment of a bi-rotational hydraulic motor 10 employing the present invention. As explained in detail below, the same motor 10 may be operated in either a clockwise or counter-clockwise manner with or without a case drain depending on the application pressure specifications.
Motor 10 includes a first port 12 and a second port 14 formed in a front housing 11 wherethrough hydraulic fluid flows in the manner to be described. A gerotor 16 having an inner rotor 16a and outer rotor 16b is mounted upon a shaft 18 having first and second ends 18a, 18b, respectively, with second end 18b extending outwardly from housing 20 for connection to a device (not shown) to be driven by motor 10. Shaft 18 is keyed to inner rotor 16a and rotates therewith while outer rotor 16b rotates within a central opening defined by ring plate 22 in which gerotor 16 is located. Outer rotor 16b is axially offset from inner rotor 16a to create a variable space 24 therebetween as best seen in
Description will first be directed to obtaining a clockwise (“CW”) rotation of shaft 18 as viewed looking into ports 12, 14 in
Referring to
A thrust plate 26, bearings 28 and seals 30 are located on the side of gerotor 16 opposite ports 12, 14. Thrust plate 26 is mounted on shaft 18 between gerotor 16 and a tapered shoulder 18c defined on shaft 18. A bearing assembly having one or more bearings, for example a double-race bearing 28 as shown, is mounted on shaft 18 adjacent to and on the side of thrust plate 26 opposite gerotor 16. One or more lip seals 30 are mounted on shaft 18 adjacent to and on the side of bearing 28 opposite thrust plate 26. Bearing 28 and lip seals 30 may be enclosed in a rear housing 32 having a radially inwardly extending flange 33 defining an aperture 33a wherethrough shaft 18 extends exteriorly of rear housing 32 (see
During clockwise “CW” operation of motor 10, lubrication of bearing 28 is provided by hydraulic fluid from inlet port 12 which leaks along shaft 18 past gerotor 16 and thrust plate 26 to and through bearing 28.
Lip seals 30 prevent fluid from travelling any further along shaft 18 exteriorly of rear housing 32. Lip seals 30 have a predetermined maximum pressure rating which, if exceeded, may cause premature failure of the seals 30 and a breakdown of the components of motor 10. It is therefore required that the pressure in bearing 28 and seal area not exceed the maximum pressure rating of the seals 30 as discussed further below.
Shaft 18 includes a cross-drilled hole 36 which opens to the space 40 defined between bearing 28 and lip seal 30. Hole 36 extends radially inwardly inside shaft 18 and connects to a first end 38b of a longitudinally extending axial passageway 38 which extends through the center of shaft 18 to an opening 38a at first shaft end 18a. Shaft first end 18a telescopes within a needle bearing 42 which is located within a cooperatively formed bearing wall 44a of central cavity 44 formed in front housing 11. Shaft opening 38a is in fluid communication with central cavity section 44b wherein hydraulic fluid may enter from passageway 38. A cross-drilled hole 46 extends from cavity section 44b to the outer bottom wall of front housing 11 to form a case drain which may be opened or closed with a removable plug 48 as required as will be explained further below.
As stated above, lubrication of bearing 28 is provided by hydraulic fluid which has entered inlet port 12 and leaked along shaft 18 past gerotor 16 and thrust plate 26 (hereinafter referred to as “lubrication fluid”). Lubrication fluid thus passes through bearing 28 and may accumulate in space 40 defined in part by seal 30, and continue flowing through cross hole 36 and passageway 38 to front housing cavity 44b whereupon it stops if plug 48 is in place.
As seen best in
In certain applications of motor 10, the passage of lubricating fluid through aperture 56 is sufficient to maintain a safe pressure at the seal area (i.e., a pressure that does not exceed the maximum pressure rating of the seal). In this instance, a case drain is not required and plug 48 may remain in place. In other applications of motor 10, the passage of lubricating fluid through aperture 56 is not sufficient to maintain a safe seal pressure thereby requiring removal of case plug 48 so that lubricating fluid can also travel through shaft channels 36 and 38 and exit at the case drain and thereby reduce the pressure at the seal area.
Referring to
Discussion is now turned to operating motor 10 in a counter-clockwise “CCW” manner Referring again to
It will thus be appreciated that the same motor 10 may be operated in either a clockwise or counter-clockwise manner with or without a case drain depending on the application pressure specifications.
Number | Name | Date | Kind |
---|---|---|---|
4362479 | Pahl | Dec 1982 | A |
4480972 | Zumbusch | Nov 1984 | A |
4881880 | Dlugokecki | Nov 1989 | A |
6174151 | Yarr | Jan 2001 | B1 |
6193490 | White | Feb 2001 | B1 |
Number | Date | Country |
---|---|---|
20020038956 | May 2002 | WO |
WO 0238956 | May 2002 | WO |
Number | Date | Country | |
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20110206549 A1 | Aug 2011 | US |