The present disclosure relates generally to hydraulic control systems. More particularly, the present disclosure relates to control systems for controlling the speed of a hydraulic motor.
Crane and winch applications often use hydraulic motors that have high and low operating speeds. High speed is used to move the winch or crane rapidly in an unloaded condition, and low speed is used when the crane or winch is loaded. In this type of system, a problem can exist when the winch or crane operator chooses to operate the hydraulic motor at a high speed when lowering a heavy load. The heavy load coupled with a high speed of travel in a downward direction can overcome the hydraulic motors torque capacity to control the load. This can cause motor failure and dropping of the load. Also, to a lesser degree, if the operator chooses to raise a heavy load in high speed, the motor may not have the torque necessary to raise it.
One aspect of the present disclosure relates to a speed control system for controlling the speed of a hydraulic motor. The speed control system is configured to prevent the hydraulic motor from operating at a speed where the torque capacity of the hydraulic motor is less than the load on the hydraulic motor. In certain examples, the load on the hydraulic motor is determined based on a system pressure corresponding to the hydraulic motor. In certain examples, the speed control system and motor are used in combination with a system for lifting and lowering loads such as a crane or winch system.
Another aspect of the present disclosure relates to a speed control system for a hydraulic motor that forces the hydraulic motor to be operated at a low speed when a system pressure corresponding to the hydraulic motor exceeds a threshold pressure value. In certain examples, a pressure relief valve is used to sense the system pressure. In certain examples, the motor is controlled by a two-speed control valve that allows the hydraulic motor to be operated in either a low-speed mode or a high-speed mode. In certain examples, the volume of fluid displaced by the hydraulic motor for each rotation of the motor shaft is lower when the hydraulic motor is operated in the high-speed mode as compared to when the hydraulic motor is operating in the low-speed mode. In certain examples, hydraulic motor has a higher torque rating when operating in the low-speed mode as compared to when the hydraulic motor is operating in the high-speed mode. Thus, the high-speed mode can be referred to as a low-torque mode and the low-speed mode can be referred to as a high-torque mode. In certain examples, the hydraulic motor is a variable displacement hydraulic motor having a swash plate that is moved to control the amount of displacement provided for each rotation of the shaft of the hydraulic motor. In certain examples, the position of the swash plate is controlled by an actuator including a two-position speed control valve that causes the hydraulic motor to operate in the high-speed mode when in a first valve position and causes the hydraulic motor to operate in the low-speed mode when in a second valve position. In certain examples, the two-speed control valve can be moved between the first and second valve positions by a hydraulic control signal (e.g., a pilot signal) or by an electronic signal applied to a driver such as a solenoid.
In a further example, the present disclosure relates to a hydraulic system including a variable displacement hydraulic motor for lifting and lowering a load. The hydraulic motor has a first operating speed and a second operating speed. The first operating speed is higher than the second operating speed. The hydraulic motor has a first displacement value corresponding to the first operating speed and a second displacement value corresponding to the second operating speed. The first displacement value is less than the second displacement value. In certain examples, a displacement value is the volume of displacement corresponding to the hydraulic motor for each rotation of a shaft of the hydraulic motor. The hydraulic system also includes an actuator for controlling whether the hydraulic motor is operating at the first operating speed or at the second operating speed. The hydraulic system further includes a pressure sensor for sensing when a system pressure corresponding to the hydraulic motor exceeds a threshold pressure value. The hydraulic system further includes a speed control system that controls the actuator such that the hydraulic motor is prevented from operating at the first operating speed when the system pressure exceeds the threshold pressure value.
A variety of additional inventive aspects will be set forth in the description that follows. The inventive aspects can relate to individual features and to combinations of features. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the broad inventive concepts upon which the examples disclosed herein are based.
In one example, the hydraulic motor 22 is an axial piston motor that includes a swash plate 28 that can be moved to adjust the rate of displacement of the hydraulic motor 22. In certain examples, the swash plate 28 can be positioned at a first orientation that corresponds to a high-speed mode of the hydraulic motor 22 and a second orientation that corresponds to a low-speed mode of the hydraulic motor 22. In the high-speed mode, the hydraulic motor 22 operates at a relatively high speed, has a relatively small displacement value, and has a relatively low torque rating. As used herein, the phrase “displacement value” represents the volume of hydraulic fluid displaced through the hydraulic motor 22 during one rotation of the drive shaft 24. When the hydraulic motor 22 is operating in the low-speed mode, the drive shaft 24 rotates at a relatively slow speed, the hydraulic motor 22 has a relatively high displacement value and the hydraulic motor 22 has a relatively high torque value. It will be appreciated that the hydraulic motor 22 has a slower shaft speed, higher displacement value and higher torque rating when operating in the low-speed mode as compared to the high-speed mode. In one example, the hydraulic motor 22 operates at full/maximum displacement when in the low-speed mode. In one example, when the hydraulic motor 22 is operating in the high-speed mode, the swash plate 28 is positioned such that the displacement of the hydraulic motor 22 is less than or equal to about one-third of the maximum displacement value.
The position of the swash plate 28 is controlled by an actuator 30. The actuator 30 includes a hydraulic drive 32 mechanically coupled to the swash plate 28 and a two-speed control valve 34. The two-speed control valve 34 interfaces with the hydraulic drive 32 so as to control the position of the swash plate 28. In the depicted example, the hydraulic device 32 is depicted as a hydraulic cylinder having a piston 36 that reciprocates within a cylinder 38. The cylinder 38 includes a first port 40 and a second port 42. The two-speed control valve 34 selectively provides charge pressure to the first and second ports 40, 42 to control the position of the piston 36 and thus the position of the swash plate 28. As shown at
Referring still to
The hydraulic system 20 also includes a speed-control pilot line 64 for applying pilot pressure to the two-speed control valve 34 to move the two-speed control valve 34 from the first position (e.g., the left position) to the second position (i.e., the right position). As indicated above, moving the two-speed control valve 34 to the second/right position causes the hydraulic motor 22 to be operated in the low-speed mode. As shown at
In certain examples, the pressure relief valve 66 is set with a pressure relief value (e.g., a pressure threshold) that corresponds with the torque rating of the hydraulic motor 22 when operating in the high-speed mode. For example, when the hydraulic motor 22 is driving the device 26 so as to lift a load, the pressure on one side of the hydraulic motor 22 increases. The system pressure at the high pressure side of the hydraulic motor 22 is thus representative of the load being lifted by the device 26. The threshold pressure of the pressure relief valve 66 can be set to a pressure that corresponds to a load value that approaches a load that is too heavy for the hydraulic motor 22 to handle when operating in the high-speed mode given the relatively low torque rating corresponding to the high-speed mode. Thus, the selected pressure threshold is related to the value of the torque rating of the hydraulic motor 22 when operating in the high-speed mode.
The hydraulic system 20 further includes an operator control line 78 that extends between the speed control pilot line 64 and the charge pressure line 50. An operator control valve 80 is positioned along the operator control line 78. The operator control valve 80 is moveable between a first position (e.g., an upper position as shown) where the operator control valve 80 closes fluid communication through the operator control lines 78 and a second position (e.g., a lower position) in which fluid communication through the operator control line 78 is opened between the charge pressure line 50 and the speed control pilot line 64. It will be appreciated that the position of the operator control valve 80 can be controlled by the operator (e.g., via a switch or other structure). For example, under low load conditions, the operator can position the operator control valve 80 in the first position such that no pilot pressure is provided to the speed control pilot lines 64 and the two-speed control valve 34 remains in the position of
In use of the hydraulic system 20, when the system pressure in either of the first or second system lines 58, 62 exceeds the threshold pressure value set by the pressure relief valve 66, the pressure relief valve 66 opens thereby directing system pressure through the speed control pilot line 64 to the pressure reducing valve 68. The pressure reducing valve 68 reduces the system pressure to a pilot pressure that is compatible with the pilot arrangement of the two-speed control valve 34. The pressure reducing valve 68 includes a drain line 69 coupled to tank. The pilot pressure provided to the speed control pilot lines 64 by the pressure reducing valve 68 is applied to the two-speed control valve 34 thereby causing the two-speed control valve 34 to move from the first position (i.e., the left position as shown) to the second position (i.e., the right position). As indicated previously, when the two-speed control valve 34 is moved to the second position, charge pressure from the charge pressure line 50 causes the swash plate to be moved such that the hydraulic motor 22 operates in the low-speed mode. As shown at
During lifting of a load, hydraulic pressure from the system pump 46 drives the hydraulic motor 22 causing the load to be lifted. If the weight of the load causes the system pressure at the high pressure side of the hydraulic motor 22 to exceed the pressure threshold set by the pressure relief valve 66, pilot pressure is immediately provided to the speed control pilot line 64 through the valves 66, 68 thereby causing the hydraulic motor 22 to immediately switch to the low-pressure mode if the hydraulic motor 22 had been previously operating in the high-pressure mode or to maintain the hydraulic motor 22 in the low-pressure mode if the hydraulic motor 22 had already been operating in the low-pressure mode. To lower the load, the hydraulic motor 22 reverses direction while the high pressure side remains on the same side of the hydraulic motor 22. During lowering, the motor restricts flow to counteract the weight of the load and the load determines the pressure on the high pressure side of the motor. In other words, during lowering, the motor controls travel by regulating flow to slow and control an otherwise free fall condition. In this way, the hydraulic motor 22 provides a braking action/function. During lowering, as long as the pressure generated by the load at the high pressure side of the hydraulic motor 22 remains above the threshold pressure set by the pressure relief valve 66, the hydraulic motor 22 will be forced to remain in the low-speed mode regardless of the position of the operator control valve 80.
It will be appreciated that the various aspects of the present disclosure are applicable to both closed loop and open loop systems. Also, in certain examples, various components (e.g., valves 66, 68, 74, 76, 80) of the system can be incorporated into a bolt-on valve block 81.
While
To lift a load, hydraulic fluid from the pump 46 is pumped through system line 58, past the counterbalance valve 192 via the bypass 194, and through the motor 22 to cause the load to be lifted by the device 26. When lifting a load above a pre-determined weight, the system is forced to operate in the low speed mode as described above. When pump flow to the motor 22 is stopped, the motor stops lifting the load. The weight of the raised load applies back-pressure to the system line 58 via the motor 22. The backpressure in the system line 58 is applied against the counterbalance valve 192. When it is desired to hold the load, the counterbalance valve 192 is operated to prevent flow through the counterbalance valve 192 thereby holding the load at a constant height/elevation and maintaining constant backpressure in the system line 58. When it is desired to lower the load, the counterbalance valve 192 meters or otherwise controls flow through the line 58 in a direction away from the motor 22. In this way, the counterbalance valve 192 provides for controlled lowering of the load. During lowering of a load above a pre-determined weight, the system is forced to operate in the low speed mode as described above.
This application is a continuation of U.S. Ser. No. 15/300,187, Sep. 28, 2016, now U.S. Pat. No. 10,526,177. U.S. Ser. No. 15/300,187, is a U.S. National Stage application of PCT International Patent Application Serial No. PCT/US2015/022942, filed Mar. 27, 2015. Application Serial No. PCT/US2015/022942 claims priority to U.S. Patent Application Ser. No. 61/971,902 filed on Mar. 28, 2014, and U.S. Patent Application Ser. No. 61/977,432 filed on Apr. 9, 2014. The above-identified disclosures are incorporated herein by reference in their entireties. A claim of priority is made to above-identified disclosures to the extent appropriate.
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Number | Date | Country | |
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20200223673 A1 | Jul 2020 | US |
Number | Date | Country | |
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61971902 | Mar 2014 | US | |
61977432 | Apr 2014 | US |
Number | Date | Country | |
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Parent | 15300187 | US | |
Child | 16734899 | US |