The present invention relates to brake assemblies, and more particularly, to brake assemblies of the type intended for use with fluid pressure actuated devices such as hydrostatic motors. Although the present invention is not necessarily limited to being used with a fluid pressure actuated motor, the invention does rely, in part, on the presence of pressurized fluid for its operation, and therefore, the invention will be described in connection with a hydrostatic motor.
Although the present invention may be included advantageously with many different types of fluid pressure actuated devices, it is especially adapted for use with a low-speed, high-torque (“LSHT”) gerotor motor, and will be described in connection therewith. As is well known to those skilled in the art, brake assemblies have become an important feature of many LSHT gerotor motors, especially when such motors are utilized for vehicle propel applications. Many vehicles propelled by hydrostatic drive circuits, which include LSHT gerotor motors, are operated on hilly terrain and on work sites involving grades, such that some sort of motor braking capability is extremely desirable, if not essential, for the safe operation of the vehicle.
In many vehicle applications for LSHT gerotor motors, the motor can have a device referred to as either a parking brake or a parking lock, the term “lock” being preferred in some instances, because it is intended that the device be engaged only after the vehicle is stopped. In other words, such parking “lock” devices are not intended to be dynamic brakes, which would be engaged while the vehicle is still moving, to bring the vehicle to a stop. However, the term “brake” has also been used, and will generally be used hereinafter to mean and include both brakes and locks. The term “brake” is somewhat preferred, to refer to a device which can be applied gradually, and to distinguish from a device which would operate only fully engaged or fully disengaged.
Examples of LSHT gerotor motors incorporating brake arrangements are illustrated and described in U.S. Pat. Nos. 6,062,835; 6,132,194; and 6,321,882, all of which are assigned to the assignee of the present invention and incorporated herein by reference. The brake arrangements in the above-incorporated patents are all of the “spring-applied, pressure-released” type in which a spring biases the brake arrangement into its “engaged” condition, braking the motor output. Although the present invention is not strictly limited to use with a brake arrangement of the spring-applied, pressure-released type, such is the most common arrangement, and the invention will be illustrated and described in connection therewith.
In order to move the brake arrangement to its “disengaged” condition, permitting normal output shaft rotation, fluid pressure must be applied to a piston seated against the biasing spring, the fluid pressure biasing the piston to overcome the force of the biasing spring, moving the piston and spring to a retracted position. As is now well known to those skilled in the art, it is preferable to make the release piston area as large as possible, thereby reducing the required release pressure. However, as the release piston is made larger, the entire brake assembly becomes larger, more complicated and more expensive.
Many gerotor motors are utilized in “closed loop” hydrostatic systems in which there is some sort of charge pump providing a pilot pressure which may serve as the release pressure for the brake arrangement. However, many other LSHT gerotor motors are, instead, utilized in “open loop” hydrostatic systems in which there is no charge pump or other source of such a pilot pressure. For motors which are to be utilized in open loop systems, it is desirable to be able to utilize system pressure (i.e., the high pressure being communicated from the pump to the work circuit) as the release pressure for the brake assembly. However, in such an arrangement, the portion of system pressure required to move the release piston to its disengaged position represents a “loss” of pressure available to be converted into motor output torque. Therefore, it is desirable to have as large a piston as possible, and as low a release pressure as possible.
Unfortunately, if the release piston is made relatively large, in order to be able to disengage the brake at a very low release pressure, there is a serious potential problem when system pressure increases to 3000 psi or 4000 psi or perhaps even more. Full, relatively high system pressure acting on a large brake release piston area would result in many thousands of pounds of axial separating force within the brake assembly housing, far beyond what the brake assembly housing would be able to withstand, in the absence of extreme and very expensive measures to strengthen the brake assembly housing, and related components.
One known solution is to place a pressure reducing or relieving valve between the source of system pressure and the release chamber of the brake assembly, to make sure that the pressure in the release chamber would never exceed some predetermined, maximum pressure. However, such a pressure reducing or relieving valve would add substantially to the overall cost and complexity of the motor and brake assembly and of its plumbing installation.
Accordingly, it is an object of the present invention to provide an improved brake assembly of the type which may be utilized with a fluid pressure operated device, in which the release piston may be operated by system pressure, but which overcomes the above-described problems.
It is a more specific object of the present invention to provide such an improved brake assembly, including a relatively large release piston, in which the brake assembly limits the release pressure applied to the piston, as system pressure increases above a predetermined level.
The above and other objects of the invention are accomplished by the provision of a rotary fluid pressure device of the type including a housing defining a fluid inlet and a fluid outlet. A rotary fluid displacement mechanism includes an output member having either orbital or rotational movement. The device includes an output shaft extending axially relative to the output member and is operable to transmit the movement of the output member. The housing defines a generally cylindrical brake chamber, and a piston member disposed in the brake chamber. The piston member is moveable between a first, retracted position under the influence of fluid pressure in the brake chamber, and a second engaged position under the influence of a biasing spring disposed in engagement with a rearward side of the piston member. Braking means is operably associated with the piston member and either the output member or the output shaft, such that movement of the piston member to the second, engaged position results in braking of the output shaft.
The improved rotary fluid pressure device is characterized by the housing defining a fluid pressure port in fluid communication with the fluid inlet. The piston member defines a first, large pressure chamber in fluid communication with the fluid pressure port. The piston member defines a second, small pressure chamber in fluid communication with the fluid pressure port. A valve means is operable, when the fluid pressure in the first, large pressure chamber reaches a predetermined pressure, to communicate the first, large pressure chamber to a source of low pressure fluid.
Referring now to the drawings, which are not intended to limit the invention,
The entire motor as shown in
As is well known in the art, the gerotor gear set 23 includes an outer, internally-toothed ring member 23R, and disposed therein, an externally-toothed star member 25, which undergoes orbital and rotational movement in response to pressurized fluid being communicated from the inlet port 17 to the expanding volume chambers. The rotational movement of the star member 25 is transmitted by means of a valve drive shaft 27 to a rotatable disk valve member 29. As is also well known to those skilled in the art, the function of the rotatable disk valve member 29 is to control the communication of pressurized fluid from the inlet port 17 to the gerotor gear set, and to control the communication of low pressure, exhaust fluid from the gerotor gear set 23 to the outlet port 19.
Also in splined engagement with the star member 25 is a main drive shaft 31 (also referred to as a “dogbone” shaft) having a rearward set of crowned splines 33 in splined engagement with internal splines in the star member 25, and a forward set of crowned splines 35 in splined engagement with internal splines in an output shaft 37 (shown only fragmentarily in
The brake portion 13 comprises a forward brake housing 41 and a rearward brake housing 43, which would typically be bolted together in tight sealing engagement by a plurality of bolts (omitted from
Referring still to
The forward brake housing 41 and the rearward brake housing 43 cooperate to define a somewhat “T-shaped” (in half cross-section), generally cylindrical brake chamber 61, and disposed therein is a brake piston 63, with the reference numeral “63” being associated in
Disposed forwardly of the radial portion 63 of the brake piston is an annular washer 67, by means of which the brake piston is able to exert an axial biasing force on the brake disks 57 and 59, biasing them toward an engaged position, operable to limit rotation of the output shaft 37 relative to the brake housing 41,43 or perhaps even prevent rotation of the output shaft 37 completely. Disposed in engagement with a rearward surface of the radial portion 63 of the brake piston is a set of Belleville washers 69, seated against an adjacent surface of the rearward brake housing 43, and operable to bias the brake piston 63 and the annular washer 67 toward the engaged position.
It will be understood by those skilled in the art that the particular configuration and arrangement of the various components of the brake portion 13 which have been described up to this point are not essential features of the invention, but for reasons discussed in the BACKGROUND OF THE DISCLOSURE, it is desirable for the brake piston, and specifically, the pressure release area thereof, to be relatively large, thus reducing the fluid pressure needed to overcome the biasing force exerted by the Belleville washers (springs) 69. Therefore, in the subject embodiment, and by way of example only, and as may best be seen in
Referring now primarily to
Disposed within the fluid pressure port 73 is a valve member, shown herein, somewhat schematically, as a valve spool 75, and as system pressure begins to build, pressure and flow are communicated past the valve spool 75 and by means of a passage 77 into the release chamber 71. Those skilled in the art will recognize that a certain, predetermined volume of fluid must enter the release chamber 71 in order to compress the Belleville spring 69 to the extent necessary to disengage the clutch pack. The valve spool 75 will be described in greater detail subsequently, as the operation is described in some detail.
As the system pressure continues to rise, the fluid pressure in the release chamber 71 will bias the brake piston 63 to the right in
As the system pressure continues to rise, the pressure will eventually reach a predetermined maximum system pressure which is selected or determined such that the total area of the release chamber 71, multiplied by the predetermined maximum pressure, is equal to or less than a maximum desired axial separating force permitted to act on the forward and rearward brake housings 41 and 43. See the line marked “Predetermined Maximum Force” in the graph of
Referring still primarily to
Referring now primarily to
As the system pressure initially builds from a substantially zero pressure, a system pressure will be reached sufficient to generate a force (see the graph marked “71” in
As the system pressure continues to build, the valve spool 75 is gradually moved from the position shown in
Referring now primarily to
As may best be seen in
As the system pressure increases to a pressure greater than the predetermined, maximum pressure (1000 psi. or 68 bar in the earlier example), and the pressure in the release chamber 71 drops to case drain pressure as described previously, the only pressure maintaining the brake piston 63 in its disengaged position is the pressure in the seven release chambers 89. However, because the total area of the release chamber 89 is substantially less than that of the release chamber 71, the predetermined, maximum pressure, and the area of the release chamber 89 must be selected such that the resulting force on the brake piston 63 is greater than the force of the Belleville springs 69. Thus, it may be seen in the graph of
Thereafter, as system pressure continues to increase, the force on the brake piston 63 gradually increases (the line marked “89” in
Thus, the present invention provides a brake assembly which can operate on system pressure to disengage the brake piston at a very low system pressure (using a “large” release chamber), but which then has the large release chamber drained, and thereafter, with increasing system pressure, uses only a relatively “small” release chamber to maintain the brake piston disengaged. With the brake assembly of the present invention, the force on the brake piston never exceeds a Predetermined Maximum Force, but, after initially disengaging the piston, and as the system pressure increases, the force on the piston never drops below that necessary to maintain the piston in its disengaged condition.
The invention has been described in great detail in the foregoing specification, and it is believed that various alterations and modifications of the invention will become apparent to those skilled in the art from a reading and understanding of the specification. It is intended that all such alterations and modifications are included in the invention, insofar as they come within the scope of the appended claims.
Number | Name | Date | Kind |
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3441110 | Ruggen | Apr 1969 | A |
3680666 | Sommer | Aug 1972 | A |
4613292 | Bernstrom et al. | Sep 1986 | A |
4930312 | Metcalf | Jun 1990 | A |
4940401 | White, Jr. | Jul 1990 | A |
4981423 | Bissonnette | Jan 1991 | A |
5114324 | Spindeldreher | May 1992 | A |
6030194 | Yakimow et al. | Feb 2000 | A |
6033195 | Uppal | Mar 2000 | A |
6062835 | Acharya et al. | May 2000 | A |
6132194 | Wenker et al. | Oct 2000 | A |
6321882 | Heckel et al. | Nov 2001 | B1 |
6345968 | Shupe | Feb 2002 | B1 |
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6743002 | Millar et al. | Jun 2004 | B1 |
Number | Date | Country | |
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20060159581 A1 | Jul 2006 | US |